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The epidemiology of non-typhoidal Salmonella enterica in Australia and the impact of whole genome sequencing on public health surveillance and outbreak investigation
Laura Ford
Research School of Population Health
A thesis submitted for the degree of
Doctor of Philosophy
of The Australian National University
May 2019
© Copyright by Laura Ford 2019
All Rights Reserved
i
Statement of Contribution
This thesis is submitted as a Thesis by Compilation in accordance with
https://policies.anu.edu.au/ppl/document/ANUP_003405.
I declare that the research presented in this Thesis represents original work that I carried out
during my candidature at the Australian National University, except for contributions to multi-
author papers incorporated in the Thesis where my contributors are specified in this Statement
of Contribution.
Title: Increasing incidence of Salmonella in Australia, 2000-2013
Authors: Ford L, Glass K, Veitch M, Wardell R, Polkinghorne B, Dobbins T, Lal A, Kirk MD
Publication outlet: PLoS One
Current status of paper: Published
Contribution to paper: LF, KG, MV, RW, BP, and MDK conceived this paper. LF conducted
the data analysis with assistance from KG, RW, and AL. LF drafted the manuscript with
assistance from RW. LF coordinated co-author input and revised the manuscript as required.
Senior author’s endorsement:
Title: The epidemiology of Salmonella outbreaks in Australia, 2001-2016
Authors: Ford L, Moffatt C, Fearnley E, Sloan-Gardner T, Miller M, Polkinghorne B, Franklin
N, Williamson DA, Glass K, Kirk MD
Publication outlet: Frontiers in Sustainable Food Systems
Current status of paper: Published
Contribution to paper: LF conceived this paper with guidance from MDK and KG. LF, CM,
TS, BP, and MD decided on the methodology. LF conducted the data analysis, drafted the
manuscript, coordinated co-author input, and revised the manuscript as required.
Senior author’s endorsement:
Title: Cost of Salmonella infections in Australia, 2015
Authors: Ford L, Haywood P, Kirk MD, Lancsar E, Williamson DA, Glass K
Publication outlet: Journal of Food Protection
Current status of paper: Published
Contribution to paper: LF conceived this paper with guidance from MDK and KG. LF decided
on the methodology with PH, MDK, and KG. LF conducted the data analysis with assistance
from PH and KG. LF drafted the manuscript, coordinated co-author input, and revised the
manuscript as required.
ii
Senior author’s endorsement:
Title: Cost of whole genome sequencing for non-typhoidal Salmonella enterica
Authors: Ford L, Glass K, Williamson, DA, Sintchenko V, Robson, JMB, Stafford, R, Kirk, MD
Current status of paper: To be submitted
Contribution to paper: LF conceived this paper with guidance from MDK, KG, and DAW. LF
decided on methodology with KG. LF conducted the data analysis with assistance from KG.
LF drafted the manuscript, coordinated co-author input, and revised the manuscript as
required.
Senior author’s endorsement:
Title: Incorporating whole-genome sequencing into public health surveillance: lessons from
prospective sequencing of Salmonella Typhimurium in Australia
Authors: Ford L, Carter GP, Wang Q, Seemann T, Sintchenko V, Glass K, Williamson DA,
Howard P, Valcanis M, Castillo CFS, Sait M, Howden BP, Kirk MD
Publication outlet: Foodborne Pathogens and Disease
Current status of paper: Published
Contribution to paper: LF conceived the study with support from GPC, QW and MDK. LF,
GPC, QW, TS, VS, DAW, PH, MV, CFSC, MS, and BPH generated the data. LF conducted
data analysis, drafted the manuscript, coordinated co-author input, and revised the manuscript
as required.
Senior author’s endorsement:
Title: Seven Salmonella Typhimurium outbreaks in Australia linked by trace-back and whole-
genome sequencing
Authors: Ford L, Wang Q, Stafford R, Ressler KA, Norton S, Shadbolt C, Hope K, Franklin N,
Krsteski R, Carswell A, Carter GP, Seemann T, Howard P, Valcanis M, Castillo CFS, Bates J,
Glass K, Williamson DA, Sintchenko V, Howden BP, Kirk MD
Publication outlet: Foodborne Pathogens and Disease
Current status of paper: Published
Contribution to paper: LF conceived this study with support from RS, KAR, SN, CS, and KH.
LF, RS, KAR, SN, CS, KH, NF, RK, AC, QW, GPC, TS, PH, MV, CFS, and JB generated the
data. LF conducted data analysis. LF drafted the manuscript with direct input from QW, RS,
KAR, and SN. LF coordinated all co-author input and revised the manuscript as required.
Senior author’s endorsement:
iii
Title: Whole-genome sequencing of Salmonella Mississippi and Typhimurium Definitive Type
160, Australia and New Zealand
Authors: Ford L, Ingle D, Glass K, Veitch M, Williamson DA, Harlock M, Gregory J, Stafford
R, French N, Bloomfield S, Grange Z, Conway ML, Kirk MD
Publication outlet: Emerging Infectious Diseases
Current status of paper: Published
Contribution to paper: LF conceived this paper with guidance from MDK, KG, DAW, and
MV. LF collated data from DI, MH, SB, and ZG for further analysis. LF drafted the manuscript
with direct input from DI. LF coordinated all co-author input and revised the manuscript as
required.
Senior author’s endorsement:
Laura Ford ____________ _________________________________ 30/04/19
Candidate – Print Name Signature Date
Endorsed
Kathryn Glass _________ _________________________________ _______
Primary Supervisor – Print Name Signature Date
06/05/19
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Acknowledgments
I thank the many people and organizations who provided the data used in this thesis. In
particular, I thank the OzFoodNet Network, which is funded by the Australian Government
Department of Health. I thank the public health laboratories that performed serotyping, phage
typing, MLVA, and WGS of Salmonella isolates, including the Microbiological Diagnostic Unit
Public Health Laboratory, the Institute for Clinical Pathology and Medical Research –
Pathology West, and Queensland Health Forensic and Scientific Services. I would also like to
thank the Communicable Disease Network of Australia, state and territory health departments,
and state and territory public health officers. I particularly give thanks to ACT Health and the
Tasmanian Department of Health and Human Services, as well as their communicable disease
control teams.
I am very grateful for the wonderful supervision I received throughout my PhD candidature. I
thank the chair of my panel Martyn Kirk, my primary supervisor Kathryn Glass, and my
supervisor Deborah Williamson for their guidance, support, and expertise. I am exceedingly
thankful for their generosity and encouragement throughout this research. They each took the
time to assist with everything from big-picture ideas, to the methodology of my research, to
improving my writing. I appreciate their unique contributions and I thoroughly enjoyed working
with them.
I received funding support through an Australian Government Research Training Program
(RTP) Scholarship throughout my PhD candidature. I also thank the ANU, the Research
School of Population Health, and the National Centre for Epidemiology and Population Health
for additional funding support and other opportunities. In particular, I am grateful for receiving
the Peter Baume Travel Grant and the Vice Chancellor’s Higher Degree by Research Travel
Grant to travel to an international conference to present on research from this thesis.
Finally, I thank my friends and colleagues at the Research School of Population Health for their
wonderful support, kindness, and advice over the last few years. This experience would have
been much harder without them. I thank my family in the United States for providing me with
every opportunity that has led me here. I am forever grateful to my husband Ashley for his
unending support, and for taking wonderful care of our daughter Georgia.
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Abstract
In Australia, the rates of reported non-typhoidal Salmonella enterica infections are amongst
the highest in the industrialized world. Public health laboratories are increasingly adopting
whole genome sequencing (WGS) of non-typhoidal Salmonella enterica isolates to
characterize isolates for surveillance. In this thesis, I contribute to understanding the
epidemiology of salmonellosis and provide evidence on the use of phylogenomic salmonellosis
data for public health in Australia by examining trends in and sources of infection; costs-of-
illness and costs of WGS; and impacts of WGS on surveillance and outbreak investigation.
I analysed national surveillance data using negative binomial regression to show that most
states and territories had significantly increasing trends of Salmonella Typhimurium
notifications between 2000 and 2013. Geographic and age-specific analyses indicated the
importance of foodborne transmission for Salmonella Typhimurium, while suggesting that other
transmission pathways may be more important for non-Typhimurium serotypes. I found that
79% of the 990 Salmonella outbreaks in Australia between 2001 and 2016 were suspected or
confirmed to be transmitted through contaminated food. Most outbreaks were due to
Salmonella Typhimurium, and eggs or egg-containing foods were the most frequently identified
food vehicles.
I estimated the health care, lost productivity, and premature mortality costs of non-typhoidal
Salmonella enterica and sequelae irritable bowel syndrome (IBS) and reactive arthritis (ReA)
in Australia. Circa 2015, I estimated 90,833 salmonellosis cases, 4,312 hospitalizations, and
19 deaths at a cost of AUD 124.4 million (90% credible intervals 107.4-143.1 million) and AUD
146.8 million (90% CrI 127.8-167.9 million) when IBS and ReA were included. While WGS is
more expensive than traditional Salmonella typing methods and polymerase chain reaction
testing, it may result in cost savings if it can reduce case numbers through early detection of
outbreaks and sources of infection.
To examine the impacts of WGS on public health surveillance, prevention, and control, I
conducted two studies. Firstly, concurrent WGS and multiple locus variable-number-tandem
repeat analysis (MLVA) was performed on Salmonella Typhimurium isolated from residents of
the Australian Capital Territory for a 5 month period. Compared to MLVA, I found that WGS
was more sensitive, linking an additional 9% of isolates to at least one other isolate, and linking
cases from seven outbreaks occurring over 5 months in three Australian states and territories.
Secondly, I used phylogenomic and epidemiological risk factor data to characterize the
epidemiology and disease reservoirs for Salmonella Mississippi and Salmonella Typhimurium
definitive type 160 (DT160). Sequence and epidemiological data for isolates from humans,
animal, and environmental sources identified plausible sources of human infection from wildlife
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and environmental reservoirs and showed Australian and New Zealand isolates in distinct
clades for both serotypes. While the genetic relatedness of DT160 isolates suggested a
common reservoir, source attribution studies would be helpful for hyper-endemic serotypes
such as Salmonella Mississippi.
In this thesis, I demonstrate that the burden of Salmonella enterica in Australia is high, and
provide evidence for the formation of targeted policies and interventions to prevent infection.
My findings on using phylogenomic data will be instrumental in implementing WGS for routine
surveillance and outbreak investigations.
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Conference or workshop presentations arising from this thesis
1. Ford L. WGS and Salmonella outbreak investigations. Invited presentation at Food
Standards Australia New Zealand’s Microbial Genomics in Food Regulation workshop;
2016 November 14; Melbourne, Vic, Australia.
2. Ford L, Carter G, Wang Q, Seemann T, Stafford R, Hope K, Sintchenko V, Williamson
DA, Glass K, Kirk MD. Implementing whole genome sequencing for the surveillance of
Salmonella in the ACT. Oral presentation at The Communicable Disease Control
Conference; 2017 June 27-28; Melbourne, Vic, Australia.
3. Ford L, Ingle D, Gonçalves da Silva A, Harlock M, Veitch M, Williamson D, Glass K,
Kirk M. The emergence of Salmonella Typhimurium DT 160 in Australia among humans
and sparrows. Poster presentation at The International Conference on Emerging
Infectious Diseases; 2018 August 26-29; Atlanta, GA, USA.
4. Ford L, Ingle D, Harlock M, Veitch M, Glass K, Williamson D, Gregory J, Stafford R,
Kirk M. Genomic epidemiology of Salmonella Mississippi in Australia. Poster
presentation at The International Conference on Emerging Infectious Diseases; 2018
August 26-29; Atlanta, GA, USA.
5. Ford L, Haywood P, Kirk M, Williamson D, Glass K. The costs of non-typhoidal
Salmonella in Australia. Oral presentation at The Research School of Population Health
Student Conference, Australian National University; 2018 October 11; Canberra, ACT,
Australia.
viii
Table of Contents Chapter 1. Introduction ............................................................................................................. 1
1.1 Research motivation .................................................................................................. 1
1.2 Research themes ....................................................................................................... 3
Chapter 2. Background ............................................................................................................ 5
2.1 Salmonellosis .................................................................................................................. 5
2.2 Global burden of non-typhoidal Salmonella .................................................................... 5
2.3 Non-typhoidal Salmonella in Australia ............................................................................ 6
2.3.1 Burden ...................................................................................................................... 6
2.3.2 Cost .......................................................................................................................... 7
2.3.3 Public health surveillance of Salmonella .................................................................. 8
2.4 The impact of new Salmonella testing and typing technologies on public health
surveillance ......................................................................................................................... 12
2.4.1 Culture-independent diagnostic testing .................................................................. 12
2.4.2 Whole genome sequencing .................................................................................... 13
2.5 Conclusion .................................................................................................................... 15
Chapter 3. Trends of non-typhoidal Salmonella enterica in Australia .................................... 16
3.1 Introduction ................................................................................................................... 16
3.2 Paper ............................................................................................................................ 16
Chapter 4. Sources of non-typhoidal Salmonella enterica in Australia .................................. 28
4.1 Introduction ................................................................................................................... 28
4.2 Paper ............................................................................................................................ 28
Chapter 5. Costs of non-typhoidal Salmonella enterica in Australia ...................................... 37
5.1 Introduction ................................................................................................................... 37
5.2 Papers .......................................................................................................................... 37
Chapter 6. Impact of whole-genome sequencing on public health surveillance of Salmonella
Typhimurium ........................................................................................................................... 59
6.1 Introduction ................................................................................................................... 59
6.2 Papers .......................................................................................................................... 59
ix
Chapter 7. Impact of whole-genome sequencing on public health surveillance two non-
typhoidal Salmonella enterica serotypes ................................................................................ 75
7.1 Introduction ................................................................................................................... 75
7.2 Paper ............................................................................................................................ 75
Chapter 8. Discussion and conclusion ................................................................................... 84
8.1 Findings and implications ............................................................................................. 84
8.2 The future of Salmonella surveillance and research in Australia .................................. 90
8.3 Conclusion .................................................................................................................... 92
References ............................................................................................................................. 93
Appendix 1. Supplementary materials for chapter 3 ............................................................ 105
Appendix 2. Supplementary materials for chapter 4 ............................................................ 114
Appendix 3. Supplementary materials for chapter 5 ............................................................ 129
Appendix 4. Supplementary materials for chapter 6 ............................................................ 175
Appendix 5. Supplementary materials for chapter 7 ............................................................ 185
1
Chapter 1. Introduction
Non-typhoidal Salmonella enterica (Salmonella) infection causes acute gastroenteritis, along
with severe outcomes that occur more rarely including septicaemia, irritable bowel syndrome
(IBS), reactive arthritis (ReA) and death. Salmonellosis is an important cause of morbidity and
mortality from foodborne disease globally (Havelaar et al., 2015) and can be costly to health
care systems and society (Scharff et al., 2016). In Australia, rates of notified cases of
Salmonella are high and have more than doubled since notifiable disease surveillance began
in 1991 (Department of Health, 2019). Rates of Salmonella in Australia are much higher than
other high-income countries including the United States of America, Canada, the United
Kingdom, and much of the European Union (CDC, 2017; Government of Canada, 2019; EFSA
and ECDC, 2018). High rates and foodborne disease outbreaks have led Salmonella to be
targeted as one of two priority pathogens for attention in Australia’s Foodborne Illness
Reduction Strategy 2018–2021+ (Food Regulation, 2018).
With no human vaccine for non-typhoidal Salmonella, and treatment generally not
recommended, routine surveillance and outbreak investigation are key to reducing the burden
of illness. In Australia, an estimated 72% of Salmonella infections are transmitted through
contaminated food and outbreaks of foodborne salmonellosis are relatively common
(OzFoodNet Working Group, 2018; Valley et al., 2014). Public health surveillance and outbreak
investigation can lead to the identification of contaminated foods, as well as the identification
of persistent causes of food contamination. Epidemiological data of Salmonella transmitted
through contaminated food and other pathways is essential for the implementation of effective
prevention and control measures.
1.1 Research motivation
Understanding the epidemiology, costs, and impacts of laboratory typing for Salmonella will
help to inform public health surveillance and food safety policy, with the ultimate aim of
reducing the burden of illness in Australia. Analysing routine Salmonella surveillance and
outbreak investigation data helps to determine the magnitude of the public health problem
(Borgdoff & Motarjemi, 1997) and assists with pathogen and serotype prioritization for public
health resources. Monitoring trends through routine surveillance and outbreak data is
necessary for the early detection and response to emerging strains and sources of illness
(Groseclose et al., 2010). Examining trends of reported infection in Australia is needed to help
identify geographical differences, at risk populations, priority serotypes and sources and
reservoirs of infection, providing evidence for targeted interventions and policies for the
2
prevention and control of infection. Also, a comprehensive review of all reported foodborne
Salmonella outbreaks and their associated food vehicles is needed to provide evidence for
food safety agencies to implement standards and policies across the food chain.
Estimating the costs of illness can also inform food safety policy from farm to retail and provide
inputs for subsequent cost effectiveness of new policies and interventions that aim to reduce
contamination and therefore the burden of illness. As one of the leading causes of foodborne
gastroenteritis-associated hospitalizations and deaths in Australia, and a cause of IBS and
ReA, the burden of Salmonella is high (Kirk et al., 2014; Ford et al., 2014). While the overall
cost of foodborne disease in Australia circa 2000 was estimated at AUD 1.2 billion (Abelson et
al., 2006), the present-day costs of Salmonella and its sequelae in Australia have not been
estimated. Internationally, studies have demonstrated that Salmonella has a substantial
economic burden (Hoffmann et al., 2012, Santos et al., 2011, Scharff et al., 2016, Sundstrom,
2018) and that estimates of the cost of illness can be used to compare the burden of pathogens
for public health prioritization, and to evaluate the effectiveness of programs, policies, or
interventions for surveillance, prevention, and control of Salmonella (Gavin et al., 2018, Jain
et al., 2019, Scharff et al., 2016).
In Australia, Salmonella is routinely subtyped for public health surveillance when an isolate is
cultured from a human or non-human sample. Serotyping and molecular subtyping of
Salmonella isolates help distinguish between outbreak-related and sporadic isolates, including
closely related isolates, as well as link human cases to sources of infection (Bender et al.,
2001; Ross et al., 2011). Subtyping allows for the identification of outbreaks and non-human
sources for investigation, which eventually can result in the implementation of prevention and
control measures by food and environmental safety agencies.
The gold standard for Salmonella subtyping has been serotyping in Australia, and when the
isolate is serotyped as Salmonella Typhimurium multiple locus variable number tandem repeat
analysis is also conducted. While pulsed field gel electrophoresis (PFGE) is an important
Salmonella subtyping method globally and considered the gold standard by the PulseNet
International network (Camarda et al., 2015; WHO and FAO, 2009), it is not routinely
performed in Australian reference laboratories. Recent advances in laboratory technology has
resulted in whole genome sequencing (WGS) being used as a subtyping method for the
epidemiologic investigation and surveillance of Salmonella and other foodborne bacterial
pathogens (Deng et al., 2016). As WGS of Salmonella isolates generates the entire genetic
information of the organisms, WGS data provides higher discriminatory power to differentiate
closely related outbreaks, assist in tracking epidemiological trends, and monitor antimicrobial
resistances (Deng et al., 2016). While microbiology laboratories increasingly began using this
3
technology for Salmonella, it was unknown how public health surveillance was going to
incorporate highly technical and apparently costly data generated through WGS into
surveillance and control efforts.
Phylogenetic data generated from WGS has been used internationally to help investigate
outbreaks and during routine surveillance typing of Salmonella (den Bakker et al., 2014;
Leekitcharoenphon et al., 2014; Ashton et al., 2016; Inns et al., 2017). In addition, prospective
national surveillance of Listeria monocytogenes in Australia and the USA has shown the
benefits of using WGS for epidemiologic surveillance of a foodborne bacterial pathogen
(Jackson et al., 2016; Kwong et al., 2016). However, sequencing of Salmonella isolates is not
yet routine in all Australian public health laboratories for prospective public health surveillance.
Consequently, the impacts of whole genome sequencing on public health surveillance and
outbreak investigation of Salmonella have not been well established.
1.2 Research themes
The aim of this thesis is to understand the epidemiology of Salmonella in Australia, as well as
the impacts of whole genome sequencing on the public health surveillance and outbreak
investigation of Salmonella. I examined three research topics relating to Salmonella in
Australia in this thesis:
1. Trends and sources of infection;
2. Cost-of-illness and costs of WGS; and
3. Impacts of WGS on surveillance and outbreak control.
The thesis is a compilation of seven scientific manuscripts that address these research
themes relating to Salmonella in Australia, six of which have been published and one which
will be submitted to an international peer review journal. Papers are grouped into
chapters based on the research themes, along with chapters for background and
discussion and conclusion, which are unpublished.
Research theme 1: Trends and sources of infection
In this research theme, I investigated the trends and sources of Salmonella infection in
Australia to better understand the epidemiology of Salmonella and provide evidence of key
serotypes and geographical niches. I analysed national Salmonella surveillance data using
negative binomial regression to investigate trends, including geographic and age-specific
trends, of Salmonella Typhimurium and non-Typhimurium Salmonella separately. I used
descriptive analysis to identify trends of outbreaks and identify important food vehicles
associated with outbreaks from a national register of salmonellosis outbreaks in Australia. In
addition, I analysed phylogenomic data from WGS, investigating sources of infection of
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Salmonella Typhimurium, Salmonella Typhimurium DT 160 (DT160), and Salmonella
Mississippi.
Chapters 3 and 4 address this research theme, with papers in chapters 6 and 7 also
investigating trends and sources of infection using data generated through WGS.
Research theme 2: Cost-of-illness and costs of WGS
The goal of this research theme was to estimate how much Salmonella infections and their
sequelae cost Australian society. This estimate of cost will inform food safety policy and
provide inputs for subsequent cost effectiveness analyses of new policies and interventions. I
used complementary datasets to estimate the burden and costs of health care usage, lost
productivity, and premature mortality from Salmonella and sequelae IBS and ReA illness circa
2015. I used Monte Carlo simulation to provide 90% credible intervals around point estimates.
The second goal of this theme was to estimate the costs of WGS for Salmonella to the
Australian society, compared to costs of the current laboratory testing and subtyping practices,
to provide evidence of cost-savings as Australia moves towards routine WGS for Salmonella.
I first aimed to determine how effective the laboratory methods would have to be at preventing
illnesses to be cost neutral. I used data generated from the Salmonella cost-of-illness
estimates and laboratory method costs in a mathematical equation with Monte Carlo simulation
to determine the median threshold with 90% credible intervals. I then examined the impact on
costs if using WGS during different outbreak scenarios, modelling if a product recall or
intervention occurred at earlier time points along the epidemiological curve.
Papers in chapter 5 address this research theme.
Research theme 3: Impacts of WGS on surveillance and outbreak investigation
In this research theme I investigated the impacts of using phylogenomic data from WGS of
Salmonella isolates from humans, food, animals, and the environment for public health
surveillance and outbreak investigation to inform the use of phylogenomic Salmonella data by
epidemiologists in Australia. I conducted a prospective trial of sequencing all Salmonella
Typhimurium isolates in the Australian Capital Territory over a period of 5 months, and
evaluated WGS performance for routine public health surveillance. I reported on the
epidemiological and environmental investigations, and the use of phylogenomic data for seven
linked Salmonella Typhimurium outbreaks occurring across Australia during the WGS trial. In
addition, I integrated epidemiological and phylogenomic data to better understand
geographical niche and transmission pathways of two Salmonella strains: serotypes
Typhimurium DT160 and Mississippi. Papers in chapters 6 and 7 address this research theme.
5
Chapter 2. Background
2.1 Salmonellosis
Salmonellosis is an acute gastroenteritis illness, with symptoms including diarrhoea,
abdominal pain, nausea, and fever. Symptoms usually start 6 to 72 hours after infection and
last for 2 to 7 days (Heymann, 2015). While most people with salmonellosis recover without
treatment, dehydration or invasive infection can lead to hospitalisation or death, particularly in
high risk groups including young children, the elderly, and the immunocompromised (CDC,
2019a). In addition, salmonellosis can result in severe and disabling sequelae, as
approximately 8.8% of people with salmonellosis develop IBS and 8.5% develop reactive
arthritis ReA following their acute gastroenteritis illness (Ford et al., 2014; Haagsma et al.,
2010).
Salmonellosis is caused by Salmonella enterica, a gram-negative bacteria that can infect
humans through the ingestion of contaminated food or water, direct contact with the
environment, and direct contact with infected animals and humans (Giannella, 1996; Vally et
al., 2014). There are more than 2,500 serotypes of Salmonella enterica. Typhoidal Salmonella
serotypes are human-adapted serotypes causing septicaemia and are uncommon in
industrialized countries. Most cases of S. Typhi and S. Paratyphi in Australia are associated
with international travel (Jones et al., 2008; The OzFoodNet Working Group, 2018). Although
all non-typhoidal Salmonella serotypes can cause disease, they have a variety of hosts and
reservoirs and can differ in pathogenic potential (Jones et al., 2008; WHO 2018). In
industrialized countries, two Salmonella serotypes: Enteritidis and Typhimurium cause a
significant number of sporadic illnesses and outbreaks (WHO 2018).
2.2 Global burden of non-typhoidal Salmonella
Salmonella is an important illness globally, with the World Health Organization (WHO)
estimating that in 2010, it resulted in 153 million illnesses and 57,000 deaths worldwide
(Havelaar et al., 2015; Kirk et al., 2015). Approximately 52% of Salmonella illnesses globally
were attributed to contaminated food, with the estimated proportion of foodborne salmonellosis
varying from 46% in areas of Africa with high child and very high adult mortality to 76% in areas
of Europe with very low child and adult mortality (Hald et al., 2016; Kirk et al., 2015). Although
only about half of infections were attributed to contaminated food overall, the burden of
foodborne Salmonella from invasive and non-invasive infection on human health is high and
6
results in the most disability adjusted life years (DALYs) of the 22 foodborne bacterial,
protozoal, and viral diseases included in the WHO estimates (Kirk et al., 2015).
The costs of Salmonella to the health care system and to the community have been estimated
in some countries. In the United States of America (USA), the mean cost of illness due to
Salmonella was USD 3.67 billion in 2013 (ERS, 2013). In addition, in the USA, Salmonella had
the highest number of estimated quality-adjusted life year (QALY) loss of 14 foodborne disease
pathogens at 16,782 QALYs lost per year (Batz et al., 2014). In Sweden, while the overall cost
of foodborne Campylobacter was higher than the cost for foodborne Salmonella (€97.7 million
vs €25.3 million) due to different rates of disease, the cost per case of salmonellosis was higher
(€979 vs €1,374). A study in the United Kingdom (UK) found that the cost of two most common
serotypes of Salmonella (Typhimurium and Enteritidis) in 2008 was £6.5 million. Costs per
case were higher for S. Typhimurium (£1282) than for S. Enteritidis (£993), due to higher
spending on health service resources and more time off work for S. Typhimurium cases
(Santos et al., 2011). A study in The Netherlands estimated the costs of illness for one
extensive food-related salmonellosis outbreak at €6.8 million, or €7.5 million including outbreak
control costs (Suijkerbuijk et al., 2017). Quantifying the costs of foodborne illness and of
salmonellosis is important to prioritise pathogens for intervention and evaluate the impact of
interventions on reducing costs and disease burden (Berends et al., 1998; Duff et al., 2013;
Korsgaard et al., 2009; Lawson et al., 2009; Sundstrom et al., 2014).
2.3 Non-typhoidal Salmonella in Australia
2.3.1 Burden
In Australia, salmonellosis is an important and increasing cause of gastroenteritis, particularly
foodborne gastroenteritis. Over the last two decades, the rate of salmonellosis notified to public
health departments has more than doubled, reaching a peak of 74.7 cases per 100,000
population in 2016 (Figure 1) (Department of Health, 2019). While the rate of Salmonella
decreased in 2017 and 2018, at 57.6 cases per 100,000 in 2018, the rate was still higher than
in other high-income countries, with a notification rate of 16.67 cases per 100,000 in the USA
(CDC, 2017), 15.5 cases per 100,000 in the UK, and 19.7 cases per 100,000 in the European
Union in 2017 (EFSA and ECDC, 2018). In 2016, Canada reported a notification rate of 21.03
per 100,000 (Government of Canada, 2019) and New Zealand reported a notification rate of
23.2 cases per 100,000 (ESR, 2017). Rates of non-typhoidal Salmonella in 2017 in Europe
ranged from 4.5 cases to 108.5 cases per 100,000, with a higher rate than Australia only in
Slovakia and the Czech Republic (EFSA and ECDC, 2018).
7
Figure 1: The notification rate of non-typhoidal Salmonella spp. per 100,000 population in
Australia, 1991-2018. Based on data from the National Notifiable Disease Surveillance System
(Department of Health, 2019).
The number of notified cases of salmonellosis is believed to be only a fraction of the number
of cases in the community, as not all cases will seek medical attention and not all who seek
medical attention will be tested (Hall et al., 2008). An Australian study estimated that circa
2010, there were 56,000 cases of Salmonella in the community, approximately 40,000 of which
were caused by contaminated food (Kirk et al., 2014). This equated to a rate of 185 cases of
foodborne salmonellosis per 100,000 population, a 24% increase since circa 2000 (Kirk et al.,
2014). A proportion of people infected with Salmonella have severe or continuing illness and
circa 2010 there were an estimated 2,100 hospitalisations for foodborne salmonellosis and
6,750 sequelae illnesses of post-infectious IBS and ReA resulting from foodborne
salmonellosis (Ford et al., 2014; Kirk et al., 2014). Additionally, Salmonella was one of the
leading causes of deaths from foodborne illness in Australia, with an estimated 15 deaths circa
2010 with salmonellosis as the primary or contributing cause of death (Kirk et al., 2014). As
Salmonella is a preventable infection, the burden on the Australian community is unnecessarily
high.
2.3.2 Cost
In 2006, a report was published estimating the total cost of foodborne illness in Australia at
AUD 1.25 billion per annum (Abelson et al., 2006). This report used data from foodborne illness
estimates circa 2000 and cost estimates from 2002 and 2004, so the estimate may no longer
be accurate today in 2019. The cost estimate was for all foodborne illness and the report does
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1991
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1997
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2001
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2003
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Rat
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8
not break down the costs for each gastrointestinal pathogen (Abelson et al., 2006). The costs
of salmonellosis are likely to be substantial, with one hospital outbreak in Queensland in 1996
affecting 52 people estimated to cost the hospital more than AUD 120,000 (USD 95,000) with
additional considerable indirect costs (Searing et al., 2000). Determining the cost of Salmonella
in Australia would not only quantify the burden of illness in monetary terms, but also provide
an opportunity to evaluate the cost-effectiveness of current and future interventions to prevent
disease.
2.3.3 Public health surveillance of Salmonella
As Salmonella has a propensity to cause outbreaks of foodborne disease, public health
surveillance and outbreak investigation have been undertaken to identify food sources linked
to illness (The OzFoodNet Working Group, 2018), potentially indicating a wider problem with
the food supply. In Australian states and territories, public health surveillance of non-typhoidal
Salmonella generally have followed a series of steps shown in Figure 2 and explained in detail
below.
2.3.3.1 Notification
Surveillance starts when a notification of laboratory-confirmed Salmonella in a person’s faecal,
urine, or blood specimen is received by the local public health unit, and then reported nationally
under public health legislation (Department of Health, 2018).
2.3.3.2 Serotyping and MLVA
Cultured Salmonella isolates are forwarded from a primary pathology laboratory to a state
reference laboratory for serotyping. This involves identifying the antigenic formula of the
forwarded isolates and classifying the antigenic formula according to the White-Kauffmann-Le
Minor scheme to give each isolate a name (Issenhuth-Jeanjean et al., 2014). While there are
over 2,500 different S. enterica serotypes, less than 100 account for most human infections
(CDC, 2019b). While S. Enteritidis is the most common serotype in most countries, in Australia,
S. Typhimurium was the most frequently notified Salmonella serotype, accounting for between
33% and 48% of notifications annually over the 5-year period 2013–2017 (Hendriksen et al.,
2011; The Department of Health, 2019). Because S. Typhimurium was so common, further
subtyping was performed to differentiate isolates. Phage typing or pulse field gel
electrophoresis (PFGE) previously occurred routinely depending on the reference lab (The
OzFoodNet Working Group, 2015). As of 2016, all reference laboratories in Australia routinely
performed Multiple Locus Variable-number tandem repeat Analysis (MLVA) when isolates
were serotyped as S. Typhimurium, however, not all of these laboratories followed the same
interpretive scheme. While S. Typhimurium was responsible for around 44% of notifications
nationally, the proportion of S. Typhimurium ranged by state and territory, making up only 12%
9
Figure 2: Flow chart describing Salmonella surveillance in Australia
Patient visits a doctor
Doctor requests patient to submit a sample for testing
Patient submits a sample to a clinical pathology laboratory
Salmonella is detected in the sample at a clinical pathology laboratory
The clinical pathology
lab notifies the public
health department
The clinical pathology lab forwards
the Salmonella isolate to a
reference laboratory for subtyping
The public health
department conducts follow
up with the patient/case
Patient becomes ill
The public health department
analyses Salmonella isolate
subtyping data
A common exposure with
other cases is identified
No common exposure is
identified
Outbreak investigation
initiated
Continued investigation or
case classified as sporadic
The public health laboratory
performs serotyping and MLVA if
the case is serotyped as
Typhimurium
The public health laboratory
notifies the public health
department of subtyping results
Pat
ien
t an
d d
oct
or
Clin
ical
pat
ho
log
y
lab
ora
tory
Pu
blic
hea
lth
dep
artm
ent
Pu
blic
hea
lth
ref
eren
ce
lab
ora
tory
The clinical pathology
lab notifies
requesting doctor
10
of notifications in the Northern Territory to 67% in the Australian Capital Territory in 2012
(Department of Health, 2019; The OzFoodNet Working Group, 2018). States and territories
with a lower proportion of S. Typhimurium notifications than nationally (Northern Territory,
Queensland, Western Australia, and Tasmania), had a higher proportion of other serotypes
including S. Saintpaul, S. Virchow, S. Enteritidis, and S. Mississippi (Ashbolt & Kirk, 2006; The
OzFoodNet Working Group 2015, 2018). Although S. Enteritidis was one of the top 5 reported
serotypes in Australia in 2012, accounting for 7% of all Salmonella notifications, only 8% of
these infections were thought to be locally acquired, with 86% acquired overseas and 6% with
unknown acquisition (The OzFoodNet Working Group, 2018).
Serotyping and MLVA can help in both the detection of outbreaks and provide important
information during the investigation of outbreaks (CDC, 2019b; Ross et al., 2011). When there
is an increase in cases of a serotype, health departments often initiate an investigation (CDC,
2019a). In addition, knowing what serotypes predominate in what region may assist in
hypothesis generation regarding the origin of infection (Hendriksen et al., 2011). Highly
discriminatory typing is also important. A study on using MLVA for the investigation of S.
Typhimurium clusters in South Australia found that MLVA provided different but complimentary
information by subdividing phenotypically closely-related isolates for investigation (Ross et al.,
2011). Serotyping and MLVA for public health surveillance must be performed and rapidly
reported to epidemiologists to enable timely outbreak detection and implementation of
interventions to prevent further illness (Ethelberg et al., 2007; Hendriksen et al., 2011).
2.3.3.3 Case follow up and analysis of subtyping data
Epidemiological information is obtained by interviewing all cases, or cases with a serotype or
subtype of interest, through case follow up. Gathering case exposure data is key to successful
investigations and interventions. Serotyping and MLVA data from public health reference
laboratories is analysed to identify types that are above baseline levels. Cases with these types
were often prioritised for follow up. Health department interviews of infected cases captured
information about potential exposures, such as: occupation, travel, environmental exposures,
animal exposure, and food consumption history. The risk of salmonellosis has been found to
be higher in certain groups including those living in rural or remote areas, those taking proton
pump inhibitors, those reporting chicken/poultry intake at least seven times per week (Chen et
al., 2016), children under 5 years of age (CDC, 2014), and those with weakened immune
systems (CDC, 2019). There are also specific risk factors for certain Salmonella serotypes
depending on the reservoir (Doorduyn et al., 2006; Funke et al., 2017; Marcus et al., 2007;
Meyer Sauteur et al., 2013).
11
2.3.3.4 Identifying common exposures
An outbreak investigation is often initiated if a common exposure was identified among cases
or an increase in a specific subtype is observed. If no common exposure is identified among
cases with a specific subtype that is above baseline levels, further questions may be asked of
the case to generate a hypothesis for an outbreak investigation. Cases with no common
exposures, links, and/or subtypes to other cases are classified as sporadic.
2.3.3.5 Outbreak investigations
In Australia, OzFoodNet is a collaborative network of epidemiologists within state and territory
health authorities and the Commonwealth Department of Health. OzFoodNet epidemiologists
have investigated and reported on foodborne or suspected foodborne disease due to
Salmonella spp. since 2001 (Department of Health, 2017). Annual reports from 2001 to 2012,
report between 26 and 66 foodborne salmonellosis outbreaks in Australia each year (Table 1)
(Department of Health, 2018a). S. Typhimurium was the causative agent in most salmonellosis
outbreaks, although the proportion of salmonellosis outbreaks due to S. Typhimurium has
ranged from 59% in 2001 to 92% in 2011 (Table 1) (Ashbolt 2002; The OzFoodNet Working
Group, 2015). Salmonellosis outbreaks have been associated with a variety of foods including
eggs, chicken and other poultry, pork, beef, lamb, fish, fresh produce, nuts, pureed/vitamised
food, and dips (Department of Health, 2018a). Outbreaks associated with the use of raw eggs
have been particularly common. One study found that the proportion of foodborne Salmonella
outbreaks linked to eggs significantly increased in Australia between 2001 and 2011, and 90%
of these outbreaks were caused by S. Typhimurium (Moffatt et al., 2016). There were only 6
outbreaks of salmonellosis associated with drinking water reported in Australia between 2001
and 2012 (The OzFoodNet Working Group, 2006, 2007, 2015).
Table 1: Number of foodborne and suspected foodborne outbreaks due to all non-typhoidal
Salmonella and due to Salmonella Typhimurium, Australia, 2001–2012 (Department of Health,
2018a).
Year Number of outbreaks due
to Salmonella
Number (%) of outbreaks due
to Salmonella Typhimurium
2001 27 16 (59%)
2002 26 21 (81%)
2003 31 25 (81%)
2004 36 29 (81%)
2005 33 26 (79%)
2006 41 25 (61%)
2007 50 39 (78%)
12
2008 35 31 (89%)
2009 59 47 (80%)
2010 58 53 (91%)
2011 61 56 (92%)
2012 66 58 (88%)
2.4 The impact of new Salmonella testing and typing technologies on
public health surveillance
In Australia, new technologies for testing and typing Salmonella spp. are moving in divergent
directions. On one hand, the emergence of commercially produced polymerase chain reaction
(PCR) kits for the diagnosis of salmonellosis allows for quick and sensitive Salmonella
detection without having to culture an isolate (also known as culture-independent diagnostic
testing). However, as an isolate is not grown, PCR tests provide limited information for public
health surveillance. On the other hand, using whole genome sequencing (WGS) for Salmonella
subtyping provides a large amount of highly discriminatory data on Salmonella isolates to
compare isolates for surveillance.
2.4.1 Culture-independent diagnostic testing
Although culture has been the foundation of clinical diagnostic testing for Salmonella, primary
pathology laboratories are increasingly adopting culture-independent diagnostic testing
(CIDT). CIDT uses methods including nucleic acid amplification tests such as PCR and
antigen-based methods to detect Salmonella DNA in a specimen (Cronquist et al., 2012).
Using CIDT, the laboratory does not need to grow a culture of Salmonella, which yields results
much quicker, is more sensitive, and is less expensive (Cronquist et al., 2012). However, as
an isolate is not grown, the Salmonella cannot be further typed. While there may be many
advantages of using CIDT from a clinical perspective, from a public health surveillance
perspective, there are more challenges than advantages, including a loss of subtyping for
outbreak detection and decreased ability to monitor disease trends (Cronquist et al., 2012).
In Australia, CIDT using a multiplex PCR test began to be widely used by primary pathology
laboratories from late 2013 (May et al., 2017). Notification rates of non-typhoidal Salmonella
increased by 22% nationally from 2013 to 2014, which was the largest annual recorded
increase in rate since the National Notifiable Disease Surveillance System began (Department
of Health, 2019). The extent that CIDT had on this rate increase is unknown. A survey in the
United States of FoodNet clinical laboratories between 2012 and 2014 found that only a small
proportion (1.3%) of laboratories were using CIDT, but in those laboratories, 60% of specimens
were not being cultured and 3% did not yield a pathogen when cultured (Iwamoto et al., 2015).
13
The number of laboratories using CIDT increased between 2013 and 2016 from <1% of
laboratories to 14% of laboratories, resulting in 7.6% of infections in 10 USA FoodNet sites
being CIDT positive-only in 2016 (Marder et al., 2017). CIDT without culture will result in a loss
of Salmonella serotyping and other typing information, which presents challenges to public
health surveillance.
2.4.2 Whole genome sequencing
Traditional Salmonella typing methods, such as serotyping and MLVA, have been successfully
used to differentiate salmonellosis cases for public health surveillance and outbreak
investigation, helping to save lives and reduce costs to human health and industry (Scharff et
al., 2016). WGS has emerged as an alternative to these traditional typing methods (Deng et
al., 2016). WGS is a group of laboratory techniques that are used to read and order nucleotides
within a genome (Nature Education, 2014). As sequences contain the entirety of the genetic
information of an organism, WGS provides highly discriminatory data to compare bacterial
foodborne disease strains, such as Salmonella, as well as providing information on
evolutionary context, virulence and antibiotic resistance markers, and in silico prediction of
phenotypic traits (Deng et al., 2016; Jenkins, 2015; Kwong et al., 2009; Public Health England,
2014).
In September 2013, the USA began to use WGS to characterise foodborne disease pathogens,
starting with Listeria monocytogenes (CDC, 2016; Jackson et al., 2016). The US Centers for
Disease Control and Prevention (CDC) found that WGS allowed scientists to detect more
clusters of L. monocytogenes illness, solve more L. monocytogenes outbreaks while they are
still small, link cases to likely food sources, and identify new food sources of infection (CDC,
2016). The US CDC is expanding their WGS program to characterise other foodborne disease
pathogens including Campylobacter, Shiga toxin-producing Escherichia coli (STEC) and
Salmonella (CDC, 2016). They now use WGS for almost all investigations of outbreaks caused
by foodborne bacteria (CDC, 2019c). Like the US CDC, Public Health England has also
implemented WGS as a routine typing tool for foodborne disease pathogens, including
routinely sequencing all Salmonella isolates from April 2015 (Ashton et al., 2016). In addition,
the European Centre for Disease Prevention and Control has committed to moving towards
using WGS as the choice method for typing microbial pathogens over the next five years
(ECDC, 2015, 2016). By mid-2017, while the vast majority of national public health reference
laboratories in EU countries have access to whole genome sequencing, challenges with the
costs and lack of expertise may limit it uses (ECDC 2018). Australia began to use WGS for
national surveillance of L. monocytogenes in 2014 (Kwong et al., 2016) and has used WGS
for Salmonella to investigate outbreaks and for research purposes (Arnott et al., 2018; Graham
et al., 2018; Lindsay et al., 2018; Thompson et al., 2017).
14
As WGS provides a large amount of highly discriminatory data, the use of WGS to differentiate
Salmonella and other foodborne disease pathogens will affect how data are analysed and
interpreted for public health surveillance and public health action. However, while several
public health agencies are using WGS for foodborne disease characterisation and outbreak
investigation, the adoption of WGS has not been systematic.
One challenge for implementing WGS is that there is limited evidence on the effective and
actionable use of WGS data within a public health unit for surveillance. The generation and
use of WGS data for public health action requires the close collaboration between
microbiologists, bioinformaticians and epidemiologists, and using new skills and tools for the
integration of WGS, epidemiological, and clinical data (WHO, 2018a). The receipt of timely and
usable data is also important for public health action.
An advantage of using WGS for surveillance is that it provides more detailed evolutionary data
on foodborne disease isolates than other molecular methods (Ju et al., 2012; Rahaman et al.,
2015). Examining evolutionary framework, dynamics and population structure of pathogens
can help increase the understanding of trends in distribution and infection (Deng et al., 2015),
estimate how fast the disease is spreading, help predict its spread (Neher and Bedford, 2018),
lead to better control measures (Bergholz et al., 2018), and assist with detailed epidemiological
surveillance (Holmes et al., 2015). However, the public health workforce needs the skills and
tools to use evolutionary data acquired from WGS and a sufficient number of isolates need to
be sequenced to provide contextual information in order to understand disease trends for
public health action. While microbiologists and bioinformaticians are best placed to provide
training and create or adopt tools for using WGS data, it must be done in consultation with
epidemiologists and other public health staff to ensure that the training and tools are what is
needed to provide evidence for public health action.
Additionally, WGS offers advantages over traditional typing methods for identifying outbreaks.
A number of studies have shown that WGS offers improved discrimination compared to
traditional typing methods so that outbreaks of foodborne disease can be detected more easily
(Ashton et al., 2015; Inns et al., 2015, 2017; Jackson et al., 2016). Using WGS has shown to
increase confidence that isolates included in genetically related clusters are cases and shown
to provide more precise data to direct public health investigation and response resources
(Holmes et al., 2015; Jensen et al., 2016). Sequence data from food and environmental
isolates can also be very useful in outbreak investigations. The improved discriminatory power
of WGS can provide a higher level of confidence either to implement control and prevention
measures for a food source or point of contamination, or to rule out associations with food
sources in order to prevent unnecessary public health action (Byrne et al., 2014; Dallman et
15
al., 2015; Deng et al., 2016; Jensen et al., 2016). For the most effective use of WGS to detect
outbreaks, timely sequencing data is required (Lindsay et al., 2018; Neher and Bedford, 2018).
The development of clear definitions of clusters and triggers for response is also necessary.
While the highly discriminatory nature of WGS data suggests that using WGS will improve
Salmonella surveillance and outbreak detection, another challenge to turning data into public
health action arises when that data is not standardized or shared across public health
jurisdictions. In Australia, Salmonella surveillance and outbreak investigation is largely
conducted at or below the state and territory level, with national OzFoodNet coordination when
a multi-jurisdictional outbreak is detected. If Salmonella subtyping data are not standardized
and shared, it will be difficult to connect cases across jurisdictions and link cases with
Salmonella isolates detected in the food supply. WGS data could also be shared internationally
if standardized, however this requires data storage capabilities and agreement from the global
community to share WGS and metadata.
There is a general consensus in the literature that the costs of WGS are decreasing, however
it is usually more expensive than other Salmonella subtyping methods. In addition, the initial
equipment costs and continuing reagent and technician salary costs are prohibitive for many
laboratories and unable to be adopted independently of new funding (Reuter et al., 2013, Allard
et al., 2016, Taylor et al., 2015). WGS also incurs costs for storage, quality checks, and data
analysis, which may be covered by NCBI if countries choose to use it (Allard et al., 2016);
however the need for local storage and analysis capacity is likely. While it is believed that
eventually the cost of WGS will be uniformly affordable (Rahaman et al., 2015), additional start-
up funding and sustainable funding in the long term are needed for the data to be collected for
public health surveillance. If the highly discriminatory WGS data can drive public health action
to prevent illness, it may be cost-competitive with traditional typing methods, and even CIDT.
2.5 Conclusion
Non-typhoidal Salmonella is an important foodborne illness globally and in Australia. As the
rate of non-typhoidal Salmonella in Australia is increasing and is one of the highest rates in the
industrialized world, public health surveillance, outbreak investigation, and interventions for
prevention and control of illness are important to reduce the burden in the Australian
community. Understanding the trends of Salmonella serotypes and sources of infection can
help to develop more targeted interventions. In addition, quantifying the cost of illness can help
in determining the cost effectiveness of surveillance systems and interventions. Finally, with
the emergence of CIDT and WGS, understanding the impacts of these technologies will help
with effective implementation into public health surveillance systems.
16
Chapter 3. Trends of non-typhoidal Salmonella enterica in
Australia
3.1 Introduction
In this chapter, I investigate the trends of non-typhoidal Salmonella enterica notifications in
Australia between 2000 and 2013. Salmonella is a significant cause of morbidity in Australia,
and unlike in many other places in the world, Salmonella Typhimurium the most commonly
notified serotype and etiological agent in outbreaks in Australia. While publically available data
from the National Notifiable Diseases Surveillance System (NNDSS) suggested that the rate
of Salmonella infections in the Australian population had increased over 2000-2013, trends in
state, age, and state and territory by S. Typhimurium and non-Typhimurium Salmonella
notifications had not previously been examined. I found that almost all states and territories
had significantly increasing trends, with annual increases of notification rates as high as 12%
(95% confidence interval 10-14%) for S. Typhimurium in the Australian Capital Territory and
6% (95% CI 5-7%) for non-Typhimurium Salmonella in Victoria. The reasons for this increase
are unknown, with no known significant changes to the surveillance system during the time
period, culture-independent diagnostic testing was not used until the end of 2013, and The
Primary Production and Processing Standard for Poultry commenced in 2012.
This work was published as an open access research article in PLoS One. The paper
contributes to an improved understanding of the epidemiology of Salmonella in Australia by
investigating geographic differences in rates, trends and serotypes, and generating
hypotheses on transmission pathways of certain serotypes for further investigation.
Supplementary tables and figures published online as a supplement to the paper can be found
in Appendix 1.
3.2 Paper
Ford L, Glass K, Veitch M, Wardell R, Polkinghorne B, Dobbins T, Lal A, Kirk MD. Increasing
incidence of Salmonella in Australia, 2000-2013. PLoS One. 2016;11(10): e0163989, doi:
10.1371/journal.pone.0163989.
RESEARCH ARTICLE
Increasing Incidence of Salmonella inAustralia, 2000-2013Laura Ford1*, Kathryn Glass1, Mark Veitch2, Rebecca Wardell1, Ben Polkinghorne3,
Timothy Dobbins1, Aparna Lal1, Martyn D. Kirk1
1 National Centre for Epidemiology and Population Health, The Australian National University, Canberra,
Australian Capital Territory (ACT), Australia, 2 Department of Health and Human Services, Hobart,
Tasmania (Tas.), Australia, 3 OzFoodNet, Australian Government Department of Health, Canberra,
Australian Capital Territory (ACT), Australia
* laura.ford@anu.edu.au
AbstractSalmonella is a key cause of foodborne gastroenteritis in Australia and case numbers are
increasing. We used negative binomial regression to analyze national surveillance data for
2000–2013, for Salmonella Typhimurium and non-Typhimurium Salmonella serovars. We
estimated incidence rate ratios adjusted for sex and age to show trends over time. Almost
all states and territories had significantly increasing trends of reported infection for S. Typhi-
murium, with states and territories reporting annual increases as high as 12% (95% confi-
dence interval 10–14%) for S. Typhimurium in the Australian Capital Territory and 6% (95%
CI 5–7%) for non-Typhimurium Salmonella in Victoria. S. Typhimurium notification rates
were higher than non-Typhimurium Salmonella rates in most age groups in the south east-
ern states of Australia, while non-Typhimurium rates were higher in most age groups else-
where. The S. Typhimurium notification rate peaked at 12–23 months of age and the non-
Typhimurium Salmonella notification rate peaked at 0–11 months of age. The age-specific
pattern of S. Typhimurium cases suggests a foodborne origin, while the age and geo-
graphic pattern for non-Typhimurium may indicate that other transmission routes play a key
role for these serovars.
Introduction
Salmonella enterica is transmitted via food, the environment, water, people and animals, andoften causes gastroenteritis in humans [1, 2]. Worldwide, Salmonella infections, excludingthose caused by S. Typhi and S. Paratyphi, were estimated in a paper published in 2010 tocause 93.8 million (90% credible interval 61.8–131.6 million) cases of gastroenteritis per year,80.3 million of which are considered foodborne [3]. Approximately 72% of salmonellosis inAustralia is estimated to be transmitted through contaminated food [1]. Common foods associ-ated with salmonellosis in outbreak investigations and source attribution studies include eggs,poultrymeat, pork, beef, dairy products, nuts, and fresh produce [4, 5, 6, 7].
PLOS ONE | DOI:10.1371/journal.pone.0163989 October 12, 2016 1 / 11
a11111
OPENACCESS
Citation: Ford L, Glass K, Veitch M, Wardell R,
Polkinghorne B, Dobbins T, et al. (2016) Increasing
Incidence of Salmonella in Australia, 2000-2013.
PLoS ONE 11(10): e0163989. doi:10.1371/journal.
pone.0163989
Editor: Dipshikha Chakravortty, Indian Institute of
Science, INDIA
Received: May 11, 2016
Accepted: August 27, 2016
Published: October 12, 2016
Copyright:© 2016 Ford et al. This is an open
access article distributed under the terms of the
Creative Commons Attribution License, which
permits unrestricted use, distribution, and
reproduction in any medium, provided the original
author and source are credited.
Data Availability Statement: The data that
underlies the findings of this study is National
Notifiable Disease Surveillance System data. We
are unable to upload the minimal data set used in
this study, as we obtained the data from a third
party. Australian Salmonella notification data, as
was used in this study, can be requested from the
Communicable Disease Network Australia. Data
requests can be sent to epi@health.gov.au.
Funding: This work was funded by the Australian
Research Council (ARC Linkage Grant
LP110200431).
17
There are over 2,500 different serovars of Salmonella [8]. The most common serovar in Aus-tralia is S. Typhimurium, which is also the most commonly identified etiological agent in out-breaks [7, 9]. S. Enteritidis is not endemic in Australian poultry layer flocks and most humaninfections with S. Enteritidis are acquired overseas [7]. Many other serovars occupy distinctecological niches and epidemiological foci in Australia, as it is a large country with wide cli-matic and geo-physical variation [7,10].
In Australia, all laboratory confirmed Salmonella infections are reported to state and terri-tory health departments, and subsequently to the National Notifiable Diseases SurveillanceSystem (NNDSS) [11]. Surveillance data are an under representation of the total burden of sal-monellosis cases, with an estimated 7 salmonellosis cases (95% CI 4–16) occurring in the com-munity for every 1 notification to health departments [12]. Circa 2010, there were an estimated40,000 salmonellosis cases attributable to contaminated food in the Australian communityeach year [13]. In addition, there were an estimated 2,100 hospitalizations, 15 deaths and 6,750complications from contaminated food [13,14].
National surveillance figures over the last decade suggest the rate of Salmonella infectionshas been increasing [15]. We compared the rates of Salmonella infections between sex, agegroups, and Australian states and territories over 2000–2013 in order to examine trends in thereported incidence of infection and identify differences between states and territories.
Materials and Methods
In this study, we used national Australian human salmonellosis notification data to analyze dis-ease trends by state and territory from 2000 to 2013. In Australia, there are six states: NewSouthWales (NSW), Queensland (Qld), South Australia (SA), Tasmania (Tas.), Victoria(Vic.), and Western Australia (WA); and two territories: the Australian Capital Territory(ACT) and the Northern Territory (NT) (Fig 1). The climate and environment varies widelyboth across and within these states and territories.We chose to examine Salmonella trends at astate and territory level due to the availability of data at that level, and evidence that suggeststhat the frequency of Salmonella serovars differs by state and territory [7].
Ethics approval for this study was granted by the Australian National University HumanResearch Ethics Committee [protocol 2012/412].
Data sources
All states and territories have public health legislation that requires doctors and/or pathologylaboratories to report any confirmed cases of salmonellosis [17]. A confirmed case requiresdefinitive laboratory evidence of the isolation or detection of Salmonella species, excluding S.Typhi, which is notified separately [18]. State-based surveillance systems have collected dataand entered all confirmed salmonellosis cases into NNDSS since 1991. We requested de-identi-fied Salmonella spp. NNDSS notifications (including ‘notification receive date’, ‘true onsetdate’, ‘diagnosis date’, ‘age at onset’, ‘sex’, ‘organism’, and ‘serogroup’ fields) for each state andterritory for 1991 to 2013 from the Communicable Disease Network of Australia (CDNA). Weused ‘diagnosis date’ for all analyses, which is defined as the date a person’s illness began(onset), or where onset date is unknown, the earliest of the specimen collection date, the datethe health professional signed the notification form or the laboratory issued the results, or thedate the notification is received by the communicable diseases section of the health authority.Due to incompleteness of serotyping data in the NNDSS in the 1990s, we restricted the data foranalysis to cases with diagnosis dates from 2000 to 2013 inclusive.
Increasing Salmonellosis in Australia, 2000-2013
PLOS ONE | DOI:10.1371/journal.pone.0163989 October 12, 2016 2 / 11
Competing Interests: The authors have declared
that no competing interests exist.
18
Rates of illness per 100,000 population were calculated using the estimated resident popula-tion by age and sex for each state and territory as of the June quarter for each year between2000 and 2013 from the Australian Bureau of Statistics (ABS) [19].
Analysis
The primary aim of the analysis was to examine the trends in reported incidence over the timeperiod.We excluded all Salmonella cases where the serovar, age, or sex was missing.We alsoexcluded infections due to S. Paratyphi A, S. Paratyphi B (except for bioser Java), and S. Paraty-phi C, as they predominantly result in enteric fever and are acquired while traveling overseas.S. Typhimurium and non-Typhimurium Salmonella were analyzed separately to examine thetrends of Australia’s most common serovar, S. Typhimurium, compared with trends of allother types of non-typhoidal Salmonella notified in Australia. Less than 0.1% of notificationswere typed as S. subspecies enterica, which were grouped with S. Typhimurium if they had anH = i in the antigenic formula or a known Typhimurium phage type (commonly known asmonophasic S. Typhimurium). We used negative binomial regression to estimate incidencerate ratios (IRR) by sex, age, and state and territory. We also included an interaction term inthe model to estimate IRRs for trend over time by state and territory. ABS population numbersby age, sex and state and territory were used as an offset to standardize the incidence rates to
Fig 1. Map of Australian States and Territories showing the crude notification rate of salmonellosis for 2013 after excluding cases with
missing data on serovar, age, or sex. Administrative boundaries from the Australian Bureau of Statistics [16].
doi:10.1371/journal.pone.0163989.g001
Increasing Salmonellosis in Australia, 2000-2013
PLOS ONE | DOI:10.1371/journal.pone.0163989 October 12, 2016 3 / 11
19
the population.We used the interaction between state/territory and year to produce a trendover time for each state and territory, with year defined as the year of diagnosis and treated as acontinuous variable. A state-by-state analysis showed that treating year as a continuous vari-able was appropriate for states and territory data (NT excepted—see S1 Fig). Age was catego-rized in one-year age groups from 0 to 4 and in 5-year age groups until 85 years and over.Analysis was performedwith Stata statistical package 12.1 (www.stata.com/) and graphs weremade using Stata and Microsoft Excel 2010. ArcGIS v10.3 (http://www.esri.com/software/arcgis) was used to create a map of the crude annual salmonellosis notification rate in 2013.
Sensitivity analysis
NNDSS data does not allow us to distinguish between sporadic and outbreak cases. To test theeffect of years with large outbreaks or a large number of sporadic cases on our rate ratio esti-mates, we removed outlier years of 2009 in ACT, 2011 in SA, and 2005 in Tas. from the S.Typhimurium analysis. An outlier year was defined as any year where there was an absolutedifference of 10 per 100,000 or greater between the crude rate and the predicted rate.
Results
There were 127,195 cases of salmonellosis reported to NNDSS with a diagnosis date between2000 and 2013. Of these notifications, 97.7% (124,235/127,195) included serovar data (S1Table) and of those, 99.6% (123,762/124,235) included age and sex data. Nationally, the crudeannual rate was lowest in 2000 (30.6 per 100,000) and increased to 53.0 per 100,000 in 2013 (S2Table). Fig 1 shows the geography of the Australian states and territories, together with thecrude notification rate of salmonellosis for 2013 by state.
Rates of both S. Typhimurium and non-Typhimurium Salmonella increased from 2000 to2013 with an IRR of 1.06 (95% CI 1.06–1.07) for S. Typhimurium and 1.03 (95% CI 1.02–1.03)for non-Typhimurium Salmonella (Fig 2). S. Typhimurium was the most frequently reportedserovar and was responsible for 43.9% (54,313/123,762) of notifications over the time period. S.Enteritidis was responsible for 5.7% (7,001/123,762) of notifications. The proportion of notifi-cations of S. Typhimurium and common non-Typhimurium serovars varied by state and terri-tory (S3 Table).
Of the salmonellosis notifications included in this analysis, 49.7% (61,557/123,762) were inmales. In the state and territorymodel, there was no significant difference between the sexesfor infectionwith non-Typhimurium Salmonella, but we found differences for S. Typhimuriuminfectionwith lower rates in males (Table 1; IRR 0.93; 95% CI 0.91–0.95). The median age at
Fig 2. Crude notification rates (dots) and negative binomial regression margins plot (lines with 95% CI) of S.
Typhimurium and non-Typhimurium Salmonella notification rates, Australia 2000–2013.
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onset of salmonellosis cases included in this study was 22 years old (range<1–108 years).Non-Typhimurium Salmonella incidence rates peaked at 0–11 months of age and S. Typhi-murium incidence rates peaked at 1–2 years of age, with a relative increase in the IRR for S.Typhimurium in those 80 years and older (Fig 3). The age distributions of cases by states andterritories were consistent with this national age distribution (S2 Fig) although there were dif-ferences in the proportion of all salmonellosis that is due to S. Typhimurium. S. Typhimuriumrates were higher than non-Typhimurium rates in most age groups in the south eastern conti-nental states (ACT, NSW, Vic., and SA), while non-Typhimurium Salmonella rates were higher
Table 1. Incident rate ratios calculated using negative binomial regression of S. Typhimurium and non-Typhimurium Salmonella by gender, age,
state and time, 2000–2013.
Typhimurium Non-Typhimurium
IRRa 95% CI b P-value IRRa 95% CIb P-value
Sex (reference = female)
Male 0.93 0.91–0.95 <0.001 1.01 0.98–1.03 0.60
Age groups (reference = <1)
1 1.28 1.18–1.39 <0.001 0.77 0.72–0.83 <0.001
2 1.04 0.96–1.13 0.35 0.33 0.31–0.36 <0.001
3 0.89 0.82–0.97 0.01 0.19 0.18–0.21 <0.001
4 0.69 0.64–0.76 <0.001 0.13 0.12–0.14 <0.001
5–9 0.41 0.38–0.45 <0.001 0.08 0.07–0.08 <0.001
10–14 0.26 0.24–0.28 <0.001 0.05 0.05–0.06 <0.001
15–19 0.27 0.25–0.29 <0.001 0.06 0.06–0.07 <0.001
20–24 0.33 0.30–0.35 <0.001 0.10 0.09–0.11 <0.001
25–29 0.29 0.27–0.31 <0.001 0.10 0.09–0.10 <0.001
30–34 0.23 0.21–0.24 <0.001 0.08 0.07–0.08 <0.001
35–39 0.17 0.16–0.19 <0.001 0.06 0.05–0.06 <0.001
40–44 0.16 0.14–0.17 <0.001 0.06 0.05–0.06 <0.001
45–49 0.14 0.13–0.16 <0.001 0.07 0.06–0.07 <0.001
50–54 0.15 0.13–0.16 <0.001 0.07 0.06–0.07 <0.001
55–59 0.14 0.13–0.16 <0.001 0.07 0.06–0.07 <0.001
60–64 0.15 0.13–0.16 <0.001 0.08 0.07–0.08 <0.001
65–69 0.16 0.14–0.17 <0.001 0.08 0.07–0.08 <0.001
70–74 0.17 0.15–0.18 <0.001 0.08 0.07–0.09 <0.001
75–79 0.17 0.15–0.19 <0.001 0.08 0.07–0.08 <0.001
80–84 0.20 0.18–0.23 <0.001 0.09 0.08–0.10 <0.001
85+ 0.22 0.20–0.24 <0.001 0.08 0.07–0.09 <0.001
Trend over time by state and territory (2000–2013)
ACT 1.12 1.10–1.14 <0.001 1.03 1.01–1.05 <0.01
NSW 1.07 1.07–1.08 <0.001 1.04 1.04–1.05 <0.001
NT 1.03 1.01–1.05 <0.01 1.02 1.00–1.03 <0.01
QLD 1.04 1.03–1.05 <0.001 0.99 0.98–1.00 0.01
SA 1.05 1.04–1.06 <0.001 1.05 1.04–1.06 <0.001
TAS 1.04 1.02–1.06 <0.001 1.04 1.02–1.05 <0.001
VIC 1.08 1.08–1.09 <0.001 1.06 1.05–1.07 <0.001
WA 1.01 1.00–1.02 0.02 1.04 1.03–1.05 <0.001
aIncidence rate ratiobConfidence interval
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in most age groups elsewhere. The two northern-most Australian states (NT and Qld.) hadhigher rates of infection in 0–4 year old children than other states and territories (S2 Fig).
At the start of the period, the incidence rate of S. Typhimurium was similar across the east-ern states and territories but was significantly higher in the western states—WA, NT and SA(Fig 4). Similarly, non-Typhimurium Salmonella rates were significantly higher in the northernand western states and territories (NT, Qld, WA, and SA) and in Tasmania than in the southeastern continental states and territories. From 2000 to 2013, the incidence rates of S. Typhi-murium significantly increased in all states and territories with the highest incidence rate ratiosin the ACT (IRR 1.12; 95% CI 1.10–1.14) and Vic. (IRR 1.08; 95% CI 1.08–1.09). During thesame time period, incidence rates of non-Typhimurium Salmonella significantly increased inall states and territories, except Queensland (IRR 0.99; 95% CI 0.98–1.00).While significant,the regression model for non-Typhimurium Salmonella in the NT did not fit the data well, andsuggests a more complex pattern over time in this territory (S1 Fig). Trends in ACT, SA, andTas. remained significant when outlier years were removed from the analysis. Individual stateand territory regression lines plotted against the crude rates for both S. Typhimurium andnon-Typhimurium Salmonella can be found in S1 Fig.
Discussion
Rates of reported salmonellosis have increased significantly in Australia during the last decadeand are at unprecedented levels. In particular, S. Typhimurium was responsible for over 40% ofnotifications and is increasing in all states and territories. There is a need for Australian healthauthorities to identify the key sources of salmonellosis serovars in different states and territo-ries to identify effectiveways to substantially reduce infection and improve control of thisemerging infection.
Fig 3. Salmonella Typhimurium and non-Typhimurium predicted notification rates with 95% CI per 100,000 by
age group, Australia, 2000–2013. Note: the first five age groups are single years to highlight the pattern of Salmonella in
young children.
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The relative importance of S. Typhimurium varies by state and territory, with higher ratesof non-Typhimurium Salmonella in tropical areas. In the Northern Territory, where the major-ity of people live in a tropical climatic zone, the rate of non-Typhimurium Salmonella wasabout 10 times higher than in most other states and territories. Queensland andWestern Aus-tralia—the only other states to have regions with tropical climatic zones—had the next highestrates of non-Typhimurium Salmonella. Analyzing specific non-Typhimurium serovars in thesestates and territories over the time periodmay help to elucidate this pattern and assist withidentifying priority serovars for investigation.
The higher incidence of S. Typhimurium in the 1–2 year old age group, compared to thoseunder 1, may indicate the importance of foodborne transmission for S. Typhimurium. This isconsistent with the results of foodborne outbreak investigations, with 92% (56/61) of Salmo-nella foodborne outbreaks attributed to S. Typhimurium in Australia in 2011 [7]. Of these, aspecific food vehicle was identified in 73% (41/56) outbreaks and 71% (29/41) were associatedwith the consumption of eggs and egg-baseddishes [7]. In addition, over the time period ofthis study, there has been a significant increase in the number of Salmonella outbreaks associ-ated with eggs, with S. Typhimurium responsible for nearly all egg-related outbreaks [20]. Ofthe 5 non-Typhimurium Salmonella outbreaks in 2011, 80% (4/5) had a known food vehicle[7]. Poultry was the responsible vehicle in 75% (3/4) of these outbreaks and the remaining out-break with a known food vehicle was associated with fruit [7]. The higher incidence of non-
Fig 4. Negative binomial regression margins plot of S. Typhimurium and non-Typhimurium
predicted notification rates by state and territory, Australia 2000–2013.
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Typhimurium Salmonella in the 0–11 month age group than in any other age group suggeststhat these serovars may have other transmission pathways, such as environmental, waterborneand zoonotic routes. An Australian expert elicitation estimated that 15% of all Salmonella ill-ness is due to environmental sources, 5% is transmitted through contaminated water, and 4%is zoonotic [1]. For example, a case control study of S. Mississippi in Tasmania found indirectcontact with native animal birds, untreated drinkingwater and travel within the state as signifi-cant predictors of infection [10] and a study in the Northern Territory found a number of non-Typhimuirum Salmonella serovars in household environments, including in animal faeces,soil, and vaccum cleaner contents [21].
Unlike in the US, Canada, China, and most of the European Union (EU), S. Enteritidis isless common than S. Typhimurium in Australia and only makes up a small proportion of noti-fications (5.7%) [22–25]. The increasing trend of salmonellosis seen in Australian states andterritories also differs from the US and European experience.Although there was no change inthe overall rate of Salmonella in 2012, compared to 1996–1998 and 2006–2008, the US saw adecrease in S. Typhimurium during this time period, as well as a decrease in the overall rate ofSalmonella in 2013 compared to 2010–2012 [22,26]. The EU has shown a significantly decreas-ing trend of Salmonella notifications from 2008–2012. Crude notification rates of salmonellosisare higher in Australia, with a rate of 49.5 per 100,000 in 2012, compared to 22.2 (range 1.8–97.5) cases per 100,000 in the EU in 2012 and 15.9 cases per 100,000 in the US in 2013 [22, 24].While Canada has seen increases in their overall rate of Salmonella between 2003 and 2009,rates were lower (16.3–18 per 100,000) than in Australia and the increase has largely been dueto S. Enteritidis [23].
There were several limitations to our analysis. We were unable to remove travel associatedcases from the data; however a previous study of data from circa 2010 found that approxi-mately 15% of Salmonella notifications were travel associated [13]. Our unit of analysis wasstate and territory, so we were unable to examine trends at a finer scale or by climatic zones. Inaddition, we could not distinguish between outbreak and sporadic cases.We could not accountfor health-seeking behavior or increases in testing, which may have influenced the IRRs of S.Typhimurium and non-Typhimurium Salmonella. Methods for further characterization of S.Typhimurium isolates vary across states and territories and including Pulse-Field Gel electro-phoresis (PFGE), multilocus variable number tandem repeat analysis (MLVA), and phage typ-ing [27–29]. Two percent of all Salmonella notifications were monophasic S. subspecies Iisolates, some of which were classifiedwith S. Typhimurium based on their serotyping andphage typing characteristics. If phage typing was not performed this may have resulted in asmall number of misclassifications in the likely serovar category. Although the method of test-ing for Salmonella remained relatively consistent over the study time period [30], we wereunable to account for any changes that may have occurred in the rate of testing.
In Australia, culture has been the mainstay of clinical diagnostic testing for Salmonella;however, there has been increased adoption of culture-independent testing in diagnostic labs.Subsequent to this analysis, in 2014, the first full year that culture-independent diagnostic test-ing (CIDT) was widely used in Australian diagnostic labs, notification rates of salmonellosisincreased by 22% nationally from 2013 to 69.7 notifications per 100,000 [15]. This is the largestrecorded annual increase in rate since notifications began and the extent of the impact CIDThad on this rate is unknown. Although CIDT provides quicker results and can be cheaper thanculture, an isolate is needed for further characterization [31]. A survey of FoodNet clinical lab-oratories in the US found that while only a small proportion of laboratories surveyed (1.3%)were using CIDT, a concerning amount of specimens were either not being cultured (60%) orculture did not yield a pathogen (3%) [32]. As whole genome sequencing (WGS), which offershighly discriminatorymolecularmarkers for cluster detection [33], becomes available for
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routine Salmonella typing, it will be important that isolates continue to be cultured and consis-tent characterizationmethods are used. CIDT without culture results in a loss of data regardingthe Salmonella serovar and other typing information, which presents challenges for outbreakidentification and monitoring disease burden and trends. Further research onWGS in the Aus-tralian setting will help determine whetherWGS can contribute to effectively detecting Salmo-nella clusters for investigation.
This study provides important insights into the epidemiology of Salmonella infections inAustralian states and territories.We observed sustained increases in both S. Typhimurium andnon-Typhimurium Salmonella between 2000 and 2013, with geographic differences in bothrates and trends. With the increasing use of CIDT, meaningful comparisons in disease ratesover timemay becomemore difficult; however novel typing methods such as whole genomesequencing offers the potential for a richer understanding of salmonellosis in Australia. Thisimproved understanding is needed to inform the control of salmonellosis in Australia.
Supporting Information
S1 Fig. State and territory crude (dots) and predicted (lines with 95% CI) notification ratesper 100,000 persons, Australia 2000–2013.(PDF)
S2 Fig. Salmonella Typhimurium and non-Typhimurium predictednotification rates per100,000 (with 95% CI) by age group for each State and Territory, 2000–2013.(PDF)
S1 Table. Number and proportion of Salmonella notificationswithout serovar data by stateand territory, Australia 2000–2013.(DOCX)
S2 Table. Salmonella spp. cases each year, the proportion of cases excluded due to missingserovar, age or sex data, crude notification rate after exclusions, S. Typhimurium notifica-tion rate, and Non-Typhimurium notification rate (per 100,000 persons, Australia 2000–2013).(DOCX)
S3 Table. Proportion (%) of S. Typhimurium and the 20 most notified non-TyphimuriumSalmonella serovars of total notifications included in this study for each state and territory,Australia, 2000–2013.(DOCX)
Acknowledgments
We would like to thank the Australian Research Council Linkage Project Team: Food Stan-dards Australia New Zealand, New SouthWales Food Authority, South Australia Health,South Australia Pathology, MicrobiologicalDiagnostic Unit Public Health Laboratory, Biose-curity South Australia, Tasmania Department of Health and Human Services, and HunterNew England Area Health.
We would also like to thank the laboratories that performed serotyping and phage typing ofSalmonella, along with the Communicable Disease Network of Australia and federal, State andTerritory health departments.
Finally, we would like to thankMary Valcanis, MicrobiologicalDiagnostic Unit PublicHealth Laboratory for her advice and expertise on grouping serovars.
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Author Contributions
Conceptualization:LF KG MV RW BPMK.
Formal analysis: LF KG RW AL.
Methodology:LF KG MV TDMK.
Writing – original draft: LF RW.
Writing – review& editing: LF KG MV RW BP TD ALMK.
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Chapter 4. Sources of non-typhoidal Salmonella enterica
in Australia
4.1 Introduction
This chapter documents the trends and sources of infection in Salmonella outbreaks in
Australia between 2001 and 2016. Over this time period, 79% of outbreaks were due to, or
suspected to be due to contaminated foods, with eggs or egg-containing foods as the most
common food vehicle in outbreaks. While few outbreaks were associated with fresh produce
(such as fruits, sprouts, some salad items, and nuts) they were generally larger than outbreaks
associated with other food vehicles.
This work contributes to an improved understanding of the epidemiology of Salmonella in
Australia by reviewing the transmission pathways, settings, serotypes, and food vehicles of
outbreaks. Identifying Salmonella serotypes and food vehicles associated with outbreaks is
important for providing evidence for sources of infection of Salmonella, as well as for prioritising
effective prevention and control measures. The paper was published in the open access
journal Frontiers in Sustainable Food Systems. Supplementary materials published online as
a supplement to the paper can be found in Appendix 2.
4.2 Paper
Ford L, Moffatt C, Fearnley E, Sloan-Gardner T, Miller M, Polkinghorne B, Franklin N,
Williamson DA, Glass K, Kirk MD. The epidemiology of Salmonella outbreaks in Australia,
2001-2016. Frontiers in Sustainable Food Systems. 2018;2:86, doi:
10.3389/fsufs.2018.00086.
ORIGINAL RESEARCHpublished: 12 December 2018doi: 10.3389/fsufs.2018.00086
Frontiers in Sustainable Food Systems | www.frontiersin.org 1 December 2018 | Volume 2 | Article 86
Edited by:
Joshua B. Gurtler,
Agricultural Research Service,
United States Department of
Agriculture, United States
Reviewed by:
Aparna Tatavarthy,
United States Food and Drug
Administration, United States
M. Leonor Faleiro,
University of Algarve, Portugal
Cheleste Thorpe,
Tufts University School of Medicine,
United States
*Correspondence:
Martyn D. Kirk
Martyn.Kirk@anu.edu.au
Specialty section:
This article was submitted to
Agro-Food Safety,
a section of the journal
Frontiers in Sustainable Food Systems
Received: 18 September 2018
Accepted: 27 November 2018
Published: 12 December 2018
Citation:
Ford L, Moffatt CRM, Fearnley E,
Miller M, Gregory J,
Sloan-Gardner TS, Polkinghorne BG,
Bell R, Franklin N, Williamson DA,
Glass K and Kirk MD (2018) The
Epidemiology of Salmonella enterica
Outbreaks in Australia, 2001–2016.
Front. Sustain. Food Syst. 2:86.
doi: 10.3389/fsufs.2018.00086
The Epidemiology of Salmonellaenterica Outbreaks in Australia,2001–2016Laura Ford 1, Cameron R. M. Moffatt 1, Emily Fearnley 1,2, Megge Miller 2, Joy Gregory 3,
Timothy S. Sloan-Gardner 4, Benjamin G. Polkinghorne 1, Robert Bell 5, Neil Franklin 1,6,
Deborah A. Williamson 7, Kathryn Glass 1 and Martyn D. Kirk 1*
1National Centre for Epidemiology and Population Health, Research School of Population Health, The Australian National
University, Canberra, ACT, Australia, 2OzFoodNet, South Australian Department for Health and Wellbeing, Adelaide, SA,
Australia, 3OzFoodNet, Department of Health and Human Services Victoria, Melbourne, VIC, Australia, 4OzFoodNet, Health
Protection Service, ACT Health, Canberra, ACT, Australia, 5OzFoodNet, Queensland Health, Brisbane, QLD, Australia,6OzFoodNet, NSW Ministry of Health, Sydney, NSW, Australia, 7Microbiological Diagnostic Unit Public Health Laboratory,
Department of Microbiology and Immunology, The University of Melbourne at The Peter Doherty Institute for Infection and
Immunity, Melbourne, VIC, Australia
Salmonella enterica is an important cause of foodborne illness in Australia, regularly
causing high-profile outbreaks involving commercially-available foods. We used the
national register of foodborne outbreaks to review the transmission pathways, settings,
serotypes, and food vehicles of Salmonella outbreaks in Australia between 2001 and
2016. We examined trends over time of implicated food vehicles in outbreaks where there
was statistical, microbiological, or descriptive evidence. Of the 990 Salmonella outbreaks
reported, 79% (778/990) were suspected or confirmed to have been transmitted through
contaminated food. Of these, 61% (472/778) occurred in food premises and 84%
(656/778) were caused by Salmonella Typhimurium. Eggs and egg-containing foods
were themost frequently identified food vehicle. Outbreaks due to egg-based sauces and
Vietnamese style sandwiches, which often contain pâté and raw egg butter, increased,
while outbreaks due to poultry meat, beef, pork, other sandwiches, and other desserts
had a decreasing trend from 2001 to 2016. Identifying food vehicles and the Salmonella
serotypes causing outbreaks in Australia provides important evidence for food regulation
strategies and control measures.
Keywords: disease outbreaks, eggs, Australia, foodborne disease, Salmonella Typhimurium
INTRODUCTION
Non-typhoidal Salmonella enterica spp. infection from contaminated food is an important causeof both sporadic gastroenteritis and outbreaks internationally. In Australia, the incidence ofinfection due to Salmonella spp. in the community is estimated to be 185 infections per 100,000population per year (Kirk et al., 2014). While only a small proportion of Salmonella cases areepidemiologically linked to outbreaks [6.6% of notifications in 2011 (OzFoodNet Working Group,2015)], outbreaks can be widespread and expensive for regulators and industry (Scharff et al., 2016).OzFoodNet—Australia’s enhanced foodborne disease surveillance network, has published annualsurveillance reports between 2001 and 2011, which report an annual median of 36 (range 26–61)salmonellosis outbreaks nationally that are confirmed or suspected to be caused by contaminatedfood, with themajority due to SalmonellaTyphimurium (OzFoodNetWorking Group, 2003, 2015).
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Ford et al. Salmonella Outbreaks in Australia
The investigation of outbreaks to identify and control thesource of infection is an essential public health action toprevent further cases. Review of the Salmonella serotypesand associated food vehicles identified during outbreakscan assist with the development of targeted population-levelinterventions and prevention strategies to reduce the incidenceof Salmonella serotypes associated with these food vehicles.International studies have attributed Salmonella outbreaks tofood commodities, finding that eggs were the most commonlyimplicated food vehicle in the United States of America (USA)(28% of outbreaks), poultry in the United Kingdom (UK) (20.5%of outbreaks), and all meats in Latin America (24% of outbreaks)(Gormley et al., 2011; Pires et al., 2012; Jackson et al., 2013;Painter et al., 2013). In Australia, outbreaks of salmonellosishave been associated with a variety of foods including eggs,chicken and other poultry, pork, beef, lamb, fish, fresh produce,and nuts (Ashbolt et al., 2002; OzFoodNet Working Group,2012). While there is evidence that outbreaks associated witheggs in Australia have increased (Moffatt et al., 2016), the foodvehicles responsible for outbreaks of salmonellosis have not beensystematically assessed before.
In this study, we used the national foodborne diseaseoutbreak register data to describe the epidemiology of foodborneSalmonella outbreaks in Australia between 2001 and 2016.
MATERIALS AND METHODS
We used the OzFoodNet outbreak register, the national registerof foodborne disease outbreaks in Australia, to examine allreported outbreaks from 1 January 2001 to 31 December 2016where non-typhoidal Salmonella spp. was listed as the etiologicalagent. Australian states and territories who investigate theoutbreaks enter standardized outbreak data into this nationalrepository, including information on: the setting of the outbreak;where the food was prepared (if applicable and defined inSupplementary Information 1); number of symptomatic cases;number of cases with laboratory-confirmed Salmonella spp.,number of cases hospitalized, number who died during theoutbreak (the relative contribution of illness due to salmonellosisto each death is unknown); median incubation period ofcases; median duration of illness; geographical location ofexposures (local government area, multiple local governmentareas, multiple health department regions, state-wide, multi-state); mode of transmission; food vehicle; type of investigation(case series, cohort, case-control) and evidence (statistical,microbiological, descriptive); and Salmonella spp. serotypeclassified in accordance with the White-Kauffmann-Le Minorscheme (Grimont and Weill, 2007).
An outbreak was defined as ≥2 cases of Salmonella spp.orientated by person, place or time, or an increase in the numberof salmonellosis cases above what is normally expected and wherean investigation was undertaken to try to determine the sourceof illness. A foodborne or suspected foodborne outbreak wasdefined as an outbreak where cases had consumed a commonfood or meal that was implicated in causing their illness.We defined statistical, microbiological, and descriptive evidenceas in Moffatt et al. (2016). If an analytical epidemiologicalstudy was undertaken with a statistically significant association
observed between a food vehicle and illness, the food vehiclewas considered to have statistical evidence. Microbiologicalevidence was obtained when Salmonella was detected or culturedfrom the implicated food vehicle, food premises, processing, orprimary production environment. Microbiological investigationsand analytical studies were not undertaken in all outbreaks.An outbreak was considered to have descriptive evidence ifthere was information collected from the epidemiological and/orthe environmental health investigations that implicated thefood vehicle, which the outbreak investigation team consideredcompelling. This would include, for example, if an unsafe foodpreparation practice of a food reportedly eaten by at least someoutbreak cases was observed during the environmental healthinvestigation.
Outbreaks where <2 people had laboratory-confirmedSalmonella spp. infection and there was no microbiologicalevidence implicating a food were excluded (n = 35). Duplicateentries of multi-state outbreaks using OzFoodNet outbreakreports (Ashbolt et al., 2002; OzFoodNet Working Group,2007) (n = 2) and outbreaks where another pathogen besidesSalmonella spp. was detected or isolated in cases (n = 3) or inthe food vehicle (n = 2) were excluded. There was one outbreakin the outbreak register included in our analysis where a serotypewas unable to be determined.
We compared the number of outbreaks per year to thenational salmonellosis notification rate using data from theNational Notifiable Disease Surveillance System (Department ofHealth, 2018). Food vehicles were grouped into food categories(Supplementary Information 1). As the food vehicle field onlycontained the name of the implicated food or meal, ingredientlists were obtained through internet-based recipe searches. Ourfood categories included egg-based sauce, desserts containingraw or lightly cooked eggs, other desserts, eggs (other), poultry,beef, pork, lamb, fish, crustacean/mollusc, fruits, vegetables,nuts, sprouts, bánh mì (Vietnamese style sandwiches), othersandwiches, salads, sushi/kimbap/gimbap, tahini or helva, dips,and mixed dishes. If there were insufficient details in thefood vehicle field to categorize the food, we categorized it asundetermined. Food vehicle categories were examined by (i)evidence type and (ii) trend over time.
Descriptive analyses were performed in Stata SE 14 (StataCorp2014) and graphs were created in Microsoft Excel 2013. Dueto the importance of S. Typhimurium in Australia, we usedchi-square tests for homogeneity to assess differences betweenoutbreaks due to S. Typhimurium and non-Typhimuriumserotypes. We used the ptrend command to calculate a chi-square statistic for trend to assess trends in food vehicles overtime. Permission for data access was granted by OzFoodNet andethics approval was obtained through the Australian NationalUniversity Human Research Ethics Committee (2017/494).
RESULTS
From 1 January 2001 to 31 December 2016, there were 990outbreaks due to Salmonella spp. reported by Australian state andterritory health authorities. The number of outbreaks reportedper year ranged from 29 outbreaks in 2001 to 116 outbreaks in2014 (Figure 1).
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Ford et al. Salmonella Outbreaks in Australia
FIGURE 1 | Salmonellosis outbreaks reported in the OzFoodNet outbreak register and National Notifiable Disease Surveillance System Salmonella notification rate,
Australia, 2001–2016.
TransmissionMost Salmonella spp. outbreaks were of foodborne or suspectedfoodborne transmission (79%; 778/990) (Table 1). In these 778outbreaks, a total of 14,708 people were reported to be ill,with a median of 9 people per outbreak (range 2–442). Overall,66% (9,683/14,708) of people affected in these outbreaks hadlaboratory-confirmed Salmonella spp., 15% (2,191/14,708) werehospitalized, and 0.3% (48/14,708) died. The median incubationperiod was available for 64% (500/778) of outbreaks, with amedian of 24 h (range of medians 7–192 h). Median illnessduration was available for 72% (560/778), with a median of 168 h(range of medians 10–504 h).
SettingImplicatedmeals were prepared in food premises for the majorityof foodborne or suspected foodborne outbreaks (Table 2),including 40% (314/778) in restaurants, 8% (63/778) in take-away stores, 7% (51/778) in bakeries, 4% (29/778) in commercialcaterers, 1% (8/778) in national franchised fast food stores,0.5% (4/778) in grocery stores/delicatessens, and 0.4% (3/778)on cruises or airlines. Home kitchens (18%, 142/778) were thenext most common setting. In 10% (80/778) of outbreaks, foodwas prepared in institutional settings, including 5% (39/778) inaged care facilities, 0.8% (6/778) in schools, 0.8% (6/778) inhospitals, 0.6% (5/778) in child care centers, 0.6% (5/778) incamps, and 2% (19/778) in other institutional settings such ascorrectional or military facilities. In the remaining 11% (84/778)of outbreaks, food was prepared at a market, fair/festival, ormobile service; commercially manufactured food; imported food;primary produce; prepared in other settings; or prepared inunknown settings (Table 2).
SerotypeThirty-nine different non-typhoidal Salmonella serotypes wereidentified among the 778 foodborne or suspected foodborne
outbreaks. Most outbreaks were due to Salmonella Typhimurium(84%, 656/778). Salmonella Saintpaul was the next most commoncause of outbreaks (2%, 15/778), followed by SalmonellaVirchow(2%, 12/778), Salmonella Singapore (1%, 9/778), Salmonellasubsp I (1%, 8/778), and Salmonella Infantis (1%, 8/778)(Table 3). No other serotype caused more than five outbreaksover the 16-year period assessed.
A higher proportion of outbreaks where food was preparedin food premises were due to S. Typhimurium (63%) thanto non-Typhimurium Salmonella (p < 0.01). There was nodifference in the reported number of S. Typhimurium and non-Typhimurium Salmonella outbreaks where food was preparedin private kitchens or in institutions. There was no differencein the number of people ill, the number of people hospitalized,the male-to-female ratio, or the median age of those affectedin foodborne or suspected foodborne outbreaks caused by S.Typhimurium compared to non-Typhimurium Salmonella in allsettings.
The number of S. Typhimurium outbreaks generally increasedover time, with 15 foodborne or suspected foodborne S.Typhimurium outbreaks reported in 2001, peaking at 88outbreaks reported in 2014. In comparison to the previousyear, in 2016, the number of S. Typhimurium outbreaks andthe associated number of cases in these outbreaks decreased,whereas, the number of associated cases in non-TyphimuriumSalmonella outbreaks increased. This was largely due to fourmulti-state non-Typhimurium Salmonella outbreaks in 2016(Figure 2).
Food VehiclesA food vehicle was listed in the OzFoodNet outbreak register for69% (537/778) of foodborne or suspected foodborne outbreaks.Of these, there was statistical and/or laboratory evidence tosupport the food vehicle as the cause of the outbreak for50% (271/537) of outbreaks. Where there was no statistical
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Ford et al. Salmonella Outbreaks in Australia
TABLE 1 | Number of reported Salmonella spp. outbreaks, ill persons, laboratory-confirmed infections, hospitalizations, and deaths by transmission pathway, Australia,
2001–2016.
Transmission Number of outbreaks
(% of total)
Number ill
(% of total)
Number laboratory
confirmed (% of ill)
Number hospitalized
(% of ill)
Number died (%
of ill)
Foodborne or suspected foodborne 778 (79) 14,708 (88) 9,683 (66) 2,191 (15) 48 (0.3)
Waterborne or suspected waterborne 13 (1) 164 (1) 101 (62) 11 (7) 1 (0.6)
Person-to-person 30 (3) 259 (2) 134 (52) 45 (17) 4 (2)
Animal-to-person 4 (0.4) 34 (0.2) 28 (82) 0 (0) 0 (0)
Unknown 165 (17) 1,585 (9) 1,440 (91) 362 (23) 9 (0.6)
Total 990 (100) 16,750 (100) 11,386 (68) 2,609 (16) 62 (0.4)
TABLE 2 | Number of reported foodborne or suspected foodborne Salmonella spp. outbreaks, ill persons, laboratory-confirmed infections, hospitalizations, and deaths
by setting food prepared, Australia, 2001-2016.
Setting Number of outbreaks
(% of total)
Number ill
(% of total)
Number lab
confirmed (% of ill)
Number hospitalized
(% of ill)
Number died (%
of ill)
Food premises 472 (61) 9,505 (65) 5,919 (62) 1,448 (15) 10 (0.1)
Home kitchens 142 (18) 1,150 (8) 664 (58) 261 (23) 2 (0.2)
Institutions 80 (10) 1,323 (9) 615 (47) 185 (14.0) 31 (2)
Market, fair/festival, or mobile service 9 (1) 102 (0.7) 64 (63) 23 (23) 0 (0)
Commercially manufactured food 10 (1) 420 (3) 412 (98) 42 (10) 4 (1)
Imported food 2 (0.3) 48 (0.3) 48 (100) 11 (23) 0 (0)
Primary produce 12 (2) 427 (3) 425 (99) 75 (18) 1 (0.2)
Other 18 (2) 500 (3) 353 (71) 43 (9) 0 (0)
Unknown 33 (4) 1,233 (8) 1183 (96) 103 (8) 0 (0)
Total 778 (100) 14,708 (100) 9,683 (66) 2,191 (15) 48 (0.3)
FIGURE 2 | Number of outbreaks and outbreak cases due to Salmonella Typhimurium and non-Typhimurium Salmonella reported by state and territory health
authorities, Australia, 2001–2016.
or laboratory evidence, the food vehicle was supported bydescriptive evidence in 38% (205/537) of outbreaks, and therewas no evidence to support the food vehicle in the remaining11% (61/537) of outbreaks. We excluded the 61 outbreaks with
no evidence from further analysis, leaving 476 outbreaks with afood vehicle listed.
In our food categories, frequently identified food vehicles inoutbreaks were eggs and egg-containing foods (Table 4). Eggs,
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Ford et al. Salmonella Outbreaks in Australia
TABLE 3 | Number of reported foodborne or suspected foodborne Salmonella spp. outbreaks, ill persons, hospitalizations, sex, and median of outbreak median age by
serotype, Australia, 2001-2016.
Serotype Number of
outbreaks (%)
Number ill
(% of total)
Number hospitalized
(% of ill)
Sex (% of ill) Median age
Male Female Unknown
Typhimurium 656 (84) 12,550 (85) 1,885 (15) 5360 (43) 6094 (48) 1096 (9) 31
Saintpaul 15 (2) 197 (1) 30 (15) 110 (56) 87 (44) 0 (0) 32
Virchow 12 (2) 127 (0.9) 21 (17) 59 (47) 66 (52) 2 (1) 28
Singapore 9 (1) 102 (0.7) 6 (6) 48 (47) 54 (53) 0 (0) 37
Infantis 8 (1) 67 (0.5) 15 (22) 26 (39) 41 (61) 0 (0) 55
Subsp I 8 (1) 91 (0.6) 15 (16) 54 (60) 37 (40) 0 (0) 28
Anatum 5 (0.6) 339 (2) 26 (8) 140 (41) 199 (59) 0 (0) 39
Bovismorbificans 4 (0.5) 138 (0.9) 34 (25) 53 (38) 38 (27) 47 (34) 34
Litchfield 4 (0.6) 108 (0.7) 8 (7) 86 (80) 22 (20) 0 (0) 46
Montevideo 4 (0.6) 62 (0.4) 10 (16) 29 (47) 33 (53) 0 (0) 27
Potsdam 4 (0.6) 101 (0.7) 15 (15) 37 (36) 64 (64) 0 (0) 34
Other 49 (6) 826 (6) 126 (15) 319 (39) 483 (58) 24 (3) 32
Total 778 (100) 14,708 (100) 2,191 (14.9) 6321 (43) 7218 (49) 1169 (8) 31
egg-based sauces (e.g., mayonnaise, aioli, hollandaise, tartare),desserts containing raw or lightly cooked eggs (e.g., tiramisu,fried ice cream, ice cream, mousse, custard), and fresh pasta eatenlightly cooked or with a lightly cooked egg based sauce, werethe identified food vehicle in 238/476 (50%) of Salmonella spp.outbreaks. S. Typhimurium was the responsible serotype in 95%(226/238) of these outbreaks (see Supplementary Information 2
for all serotypes for all food categories). Chicken and otherpoultry were the implicated food vehicle for 34/476 (7%)and pork for 15/476 (3%) outbreaks (Table 4), with 28/34(82%) and 9/15 (60%) due to S. Typhimurium, respectively(Supplementary Information 2). Other food source animals,including beef, lamb, fish, and crustaceans/molluscs, were eachidentified as the food vehicle for 1% of these outbreaks. Fruits,vegetables and sprouts were each responsible for around 1%of outbreaks, but unlike outbreaks involving animal-derivedfood vehicles, these were more common for non-Typhimuriumserotypes (p < 0.001) (Table 4; Supplementary Information 2).
Outbreaks due to sprouts, salads, Vietnamese sandwiches,fruits, nuts, tahini/helva, and dips tended to affect more people,with a median outbreak size of more than 15 cases (Table 4).Between 2001 and 2016, there was an increase in the proportionof outbreaks due to egg-based sauces (p< 0.001) and Vietnamesestyle sandwiches (p < 0.001), while poultry (p = 0.033), beef(p= 0.046), pork (p= 0.047), other sandwiches (p= 0.048), andother desserts (p = 0.017) had a decreasing trend over this timeperiod (Supplementary Information 3).
DISCUSSION
Outbreaks of non-typhoidal Salmonella spp. are a significantand high-profile cause of foodborne illness in Australia. Wefound an increasing trend of outbreaks in Australia, particularlybetween 2008 and 2014, beginning before the introduction ofculture-independent diagnostic testing (May et al., 2017). Thisis similar to the trend in the USA, where there was an increase
in the number of outbreaks reported between 2008 and 2013(Centers for Disease Control Prevention, 2018). The increasingtrend of outbreaks in Australia, together with comparativelyhigh and increasing Salmonella spp. notification rates (Fordet al., 2016), emphasizes the continued importance of identifyingfood vehicles in outbreaks and implementing control strategiesthroughout the food chain to prevent illness.
Similar to the USA and Canada, eggs and foods containing
eggs were themost commonly reported food vehicle in Australianfoodborne or suspected foodborne Salmonella spp. outbreaks
(Jackson et al., 2013; Belanger et al., 2015). Eggs were the
responsible food vehicle in 50% of these outbreaks in Australia,compared to 28% in the USA (Jackson et al., 2013) and 39% inCanada (Belanger et al., 2015). We took a conservative approachin attributing outbreaks to eggs, as eggs may have also beenthe responsible food vehicle where there was more than onehigh risk ingredient (e.g., Vietnamese style rolls, sandwiches,and salads). While the proportion of outbreaks associated withpoultry meat, beef and pork in Australia declined from 2001to 2016, egg-based sauces, desserts containing raw or lightlycooked eggs, and Vietnamese style sandwiches, which usuallycontain a raw-egg butter and/or pork or chicken liver pâté, wereincreasingly associated with Salmonella outbreaks over the timeperiod.
As most foodborne and suspected foodborne Salmonellaoutbreaks, including most S. Typhimurium outbreaks werelinked to commercial food premises, additional interventionstargeted at Salmonella control measures in these settings arerequired, particularly around the preparation of foods containingraw or lightly cooked eggs (Moffatt et al., 2016). While thereare state-based guidelines, there are no rules or restrictions onthe use of raw eggs in ready-to-eat foods in Australia (Moffattet al., 2016). As Australian states and territories have oversightof food safety regulation, some states have implemented controlmeasures across the supply chain to try to reduce the burdenof egg-related salmonellosis, including targeted communication
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Ford et al. Salmonella Outbreaks in Australia
TABLE 4 | Median number of cases affected and number of outbreaks by type of evidence due to food vehicles, Australia, 2001–2016.
Median number of
outbreak cases (range)
Outbreaks with statistical
or laboratory evidence
Outbreaks with
descriptive evidence
Total
Number % Number % Number %
Raw egg desserts* 10 (2–140) 58/106 55 48/106 45 106/476 22
Egg-based sauce 14 (2–319) 43/79 54 36/79 46 79/476 17
Eggs, other 10 (2–143) 20/47 43 27/47 57 47/476 10
Mixed dishes 10 (2–90) 24/36 67 12/36 33 36/476 8
Poultry 11 (2–391) 20/34 59 14/34 41 34/476 7
Sandwiches, other 10 (3–213) 9/24 38 15/24 63 24/476 5
Desserts, other 13 (4–202) 18/23 78 5/23 22 23/476 5
Vietnamese sandwiches 17 (2–85) 7/17 41 10/17 59 17/476 4
Pork 10 (3–27) 10/15 67 5/15 33 15/476 3
Salads 18 (3–350) 8/10 80 2/10 20 10/476 2
Sushi 9.5 (3–85) 5/8 63 3/8 37 8/476 1
Beef 8.5 (4–15) 2/6 33 4/6 67 6/476 1
Pasta 6 (3–23) 2/6 33 4/6 67 6/476 1
Lamb 6 (3–43) 3/5 60 2/5 40 5/476 1
Fish 3 (3–14) 2/5 40 3/5 60 5/476 1
Sprouts 17 (4–126) 4/5 80 1/5 10 5/476 1
Crustacean/ mollusc 4 (2–23) 2/5 40 3/5 60 5/476 1
Fruits 29 (17–144) 4/4 100 0/4 0 4/476 0.8
Vegetables 10 (5–311) 3/4 75 1/4 25 4/476 0.8
Tahini or helva 24 (3–51) 3/3 100 0/3 0 3/476 0.6
Dips 33 (2–442) 2/3 67 1/3 33 3/476 0.6
Nuts 24 (19–43) 3/3 100 0/3 0 3/476 0.6
Undetermined 18 (2–50) 19/28 68 9/28 32 28/476 6
*Desserts containing raw or lightly cooked eggs (see Supplementary Information 1 for more information)
and education for bakeries, mandatory training at retail level,industry food safety plans, and the vaccination of many layingflocks against S. Typhimurium (NSW Food Authority, 2007;Groves et al., 2016; Ford et al., 2018).
Unlike in other countries where S. Enteritidis is moreprevalent in eggs, S. Typhimurium caused most (84%) foodborneor suspected foodborne Salmonella spp. outbreaks between 2001and 2016 (Gormley et al., 2011; Pires et al., 2012; Jacksonet al., 2013; Belanger et al., 2015), with only 3 outbreaks of S.Enteritidis reported during this time period. The majority offresh produce outbreaks associated with fruits, vegetables andsprouts were caused by non-Typhimurium serotypes, with S.Saintpaul, S. Litchfield, and S. Oranienburg causing more thanhalf of the outbreaks associated with these food vehicles. Whilefew in number, outbreaks associated with sprouts, nuts, fruitand some fresh salad produce, which are usually consumed raw,were generally large due to the wide distribution of these foodproducts. Food vehicle identification is often long and difficultfor these types of fresh produce outbreaks as these foods arefrequently poorly recalled and reported by outbreak cases duringfood history interviews. Also, as most horticulture products arenot packaged and labeled and there is high product turnover, foodtrace-back investigations are difficult and associated public healthinterventions can be delayed for these reasons (Munnoch et al.,
2009). In Australia, there is currently no national horticultureprimary production and processing standard, except for seedsprouts (Food Standards Australia New Zealand, 2011), soit is important to identify interventions to target these foodvehicles.
While there have been multiple cohort or case-control studiesundertaken during outbreaks to identify the food vehicle causingillness, there have been few published case-control studies ofsporadic Salmonella illness in Australia. Without this evidence,it is difficult to compare whether the food vehicles that causeoutbreaks identified in this study are the same as those thatcause sporadic illness. Also, while individual risk factors, suchas age and sex, have been identified to be important risk factorsfor sporadic illness in Australia (Ford et al., 2016), in thisstudy, there was little difference in demographic characteristicsof cases in foodborne or suspected foodborne S. Typhimuriumand non-Typhimurium Salmonella outbreaks. This suggests thatthe individual risk factors of age and sex are not as importantin outbreaks as they are with sporadic illness. While therewas no data on the immune status of people exposed tooutbreaks, the highest number of deaths occurred in outbreaksin institutional settings, including aged care facilities andhospitals where large numbers of immunocompromised peopleare expected.
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Ford et al. Salmonella Outbreaks in Australia
A limitation of this study is that while OzFoodNetcommenced in 2001, not all states and territories were routinelyreporting data into the outbreak register until 2003, so someoutbreaks may have been missed prior to 2003. In this study,17% of Salmonella spp. outbreaks had an unknown modeof transmission. While it is likely that illness in many ofthese outbreaks was transmitted through contaminated food,there was insufficient evidence available to conclude this,so data presented in this paper is likely to under-representthe true number of foodborne outbreaks of salmonellosisin Australia. In addition to the 17% of outbreaks with anunknown mode of transmission there were: 25% of outbreaksthat had a suspected foodborne/foodborne mode of transmissionidentified with an unknown food vehicle; 6% of suspectedfoodborne/foodborne outbreaks that had no evidence to supportthe food vehicle; and the food vehicle in an additional 6%of suspected foodborne/foodborne outbreaks could not becategorized because the meal listed lacked sufficient details(undetermined) or contained multiple foods. In addition,38% of outbreaks were attributed to a food vehicle withdescriptive evidence alone. This may be because not all outbreaksare conducive to an analytical investigation (Moffatt et al.,2016), food or environmental sampling is not always routinelyperformed, or because cross-contamination can make it difficultto identify a single food vehicle. While cross-contamination islikely to be an important aspect in many outbreaks (OzFoodNetWorking Group, 2015; Osimani et al., 2016), another limitationof this study is that there was insufficient data to quantifythe importance of cross-contamination in these Australianoutbreaks.
As Australia moves toward a national strategy to reducefoodborne illness from Salmonella, data on Salmonella outbreaks,significant serotypes, and the food vehicles that cause illnessare important for monitoring and surveillance, which can beused to provide evidence for effective control measures (FoodRegulation Secretariat, 2018). Consistent with other studies,eggs and egg-containing foods were the most common causeof outbreaks in Australia over the period 2001–2016 causingsignificant morbidity in the population. Control measures have
been, and continue to be implemented around preparation ofegg-containing foods, particularly in food premises. Additionalinterventions focused on fresh produce items, such as ahorticulture primary production and processing standard, couldbe strengthened since these vehicles can cause larger outbreaks.While collecting evidence about the food vehicles that causeoutbreaks is important in the implementation of controlmeasures, it can be challenging and further research on causesof sporadic illness and the importance of cross-contaminationfor Salmonella outbreaks in Australia could identify importantpublic health interventions.
AUTHOR CONTRIBUTIONS
LF conceived the paper with feedback from all authors andconducted the analysis and drafted the paper. All authors madecontributions to the final manuscript.
FUNDING
LF is supported by an Australian Government Research TrainingProgram (RTP) Scholarship. MK is supported by a NationalHealth & Medical Research Council fellowship (APP1145997).DW is supported by a National Health & Medical ResearchCouncil fellowship (APP1123854).
ACKNOWLEDGMENTS
We thank the OzFoodNet Network, which is funded bythe Australian Government Department of Health. We thankstate public health reference laboratories who performed theSalmonella serotyping and state public health officers whoinvestigated these outbreaks.
SUPPLEMENTARY MATERIAL
The Supplementary Material for this article can be foundonline at: https://www.frontiersin.org/articles/10.3389/fsufs.2018.00086/full#supplementary-material
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Conflict of Interest Statement: The authors declare that the research was
conducted in the absence of any commercial or financial relationships that could
be construed as a potential conflict of interest.
Copyright © 2018 Ford, Moffatt, Fearnley, Miller, Gregory, Sloan-Gardner,
Polkinghorne, Bell, Franklin, Williamson, Glass and Kirk. This is an open-access
article distributed under the terms of the Creative Commons Attribution License (CC
BY). The use, distribution or reproduction in other forums is permitted, provided
the original author(s) and the copyright owner(s) are credited and that the original
publication in this journal is cited, in accordance with accepted academic practice.
No use, distribution or reproduction is permitted which does not comply with these
terms.
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Chapter 5. Costs of non-typhoidal Salmonella enterica in
Australia
5.1 Introduction
In this chapter, I investigate the cost of non-typhoidal Salmonella in Australia, and the costs of
PCR and WGS for Salmonella in terms of how these laboratory methods assist public health
action. The chapter includes two papers. The first is a cost-of-illness study describing the costs
of non-typhoidal Salmonella enterica and its sequelae illnesses from health care usage, lost
productivity, and premature mortality in a typical year circa 2015. I estimate a total cost of AUD
146.8 million (90% credible intervals 127.8-167.9 million), with 104.8 million (90% 75.5-132.3
million) from foodborne infections. Quantifying the costs of illness in Australia will assist with
prioritization for public health interventions and demonstrates that targeted interventions
across the food chain could reduce costs and societal impact. This paper is published in the
Journal of Food Protection.
In the second paper, I compare the costs of current Salmonella testing and subtyping methods
to PCR and WGS. There is evidence that WGS can enable earlier detection of outbreaks,
allowing for quicker public health action to implement control measures and prevent further
cases. Therefore, I calculated how many cases would have to be prevented using WGS before
it would cost no more than the status quo or than PCR, and examined the costs of using current
testing and subtyping methods compared with WGS in three different outbreak scenarios. The
findings suggest that WGS will result in cost savings compared to both current testing and
typing methods and PCR if its use leads to the prevention of cases. This paper will be
submitted to an international peer-review journal.
Supplementary materials for these two papers can be found in Appendix 3.
5.2 Papers
Ford L, Haywood P, Kirk MD, Lancsar E, Williamson DA, Glass K. Cost of Salmonella
infections in Australia, 2015. Journal of Food Protection. 2019;82(9):1607-1614, doi:
10.4315/0362-028X.JFP-19-105..
Ford L, Glass K, Williamson DA, Sintchenko V, Robson JMB, Stafford R, Kirk MD. Cost of
whole genome sequencing for non-typhoidal Salmonella enterica. To be submitted 2019.
Research Paper
Cost of Salmonella Infections in Australia, 2015
LAURA FORD,1 PHILIP HAYWOOD,2 MARTYN D. KIRK,1 EMILY LANCSAR,3 DEBORAH A. WILLIAMSON,4 AND
KATHRYN GLASS1*
1National Centre for Epidemiology and Population Health and 3Department of Health Services Research and Policy, Research School of PopulationHealth, The Australian National University, Canberra, Australian Capital Territory 2601, Australia (ORCID: https://orcid.org/0000-0002-6253-9672[L.F.]); 2Centre for Health Economics Research and Evaluation, University of Technology Sydney, P.O. Box 123, Broadway, New South Wales 2007,
Australia; and 4Microbiological Diagnostic Unit Public Health Laboratory, The University of Melbourne at The Peter Doherty Institute for Infection andImmunity, Parkville, Victoria 3010, Australia
MS 19-105: Received 28 February 2019/Accepted 20 May 2019/Published Online 22 August 2019
ABSTRACT
Gastroenteritis caused from infections with Salmonella enterica (salmonellosis) causes significant morbidity in Australia.In addition to acute gastroenteritis, approximately 8.8% of people develop irritable bowel syndrome (IBS) and 8.5% of peopledevelop reactive arthritis (ReA). We estimated the economic cost of salmonellosis and associated sequel illnesses in Australia ina typical year circa 2015. We estimated incidence, hospitalizations, other health care usage, absenteeism, and prematuremortality for four age groups using a variety of complementary data sets. We calculated direct costs (health care) and indirectcosts (lost productivity and premature mortality) by using Monte Carlo simulation to estimate 90% credible intervals (CrI)around our point estimates. We estimated that 90,833 cases, 4,312 hospitalizations, and 19 deaths occurred from salmonellosis inAustralia circa 2015 at a direct cost of AUD 23.8 million (90% CrI, 19.3 to 28.9 million) and a total cost of AUD 124.4 million(90% CrI, 107.4 to 143.1 million). When IBS and ReAwere included, the estimated direct cost was 35.7 million (90% CrI, 29.9to 42.7 million) and the total cost was AUD 146.8 million (90% CrI, 127.8 to 167.9 million). Foodborne infections wereresponsible for AUD 88.9 million (90% CrI, 63.9 to 112.4 million) from acute salmonellosis and AUD 104.8 million (90% CrI,75.5 to 132.3 million) when IBS and ReA were included. Targeted interventions to prevent illness could considerably reducecosts and societal impact from Salmonella infections and sequel illnesses in Australia.
HIGHLIGHTS
� The rate of salmonellosis in Australia is high, but the costs have not previously been assessed.� Salmonellosis illness and sequelae cost Australia AUD 146.8 million circa 2015.� Foodborne Salmonella infections and sequelae cost AUD 104.8 million.� Quantifying costs helps prioritize interventions across the food chain to reduce societal impact.
Key words: Cost of illness; Health care costs; Incidence; Monte Carlo methods; Salmonella infections
Acute gastroenteritis from nontyphoidal Salmonellaenterica (NTS) infection (salmonellosis) causes significantmorbidity. Globally, the World Health Organization hasestimated that NTS is one of the highest burden foodbornepathogens, responsible for approximately 78.7 millionillnesses, 59 thousand deaths, and 4 million disabilityadjusted life years in 2010 (44). In Australia, there were anestimated 262 cases per 100,000 population circa 2010, with72% of cases transmitted from contaminated food (28, 43).The reported incidence of salmonellosis in Australia hasbeen increasing and is higher than in the United States,Canada, the United Kingdom, and New Zealand (7, 12, 20,27, 35).
NTS illness is one of the leading causes of foodbornegastroenteritis-associated hospitalizations and deaths in
Australia. In addition to salmonellosis, it has been estimatedthat approximately 8.8% of people infected with NTSsubsequently develop irritable bowel syndrome (IBS) and8.5% develop reactive arthritis (ReA) (18). These chronicsequelae can be severe and require additional medical tests;treatments; visits to primary care, specialists, or hospitals;and time off work.
As the burden of salmonellosis and its sequelae arehigh, estimated costs of illness are needed to better informfood safety policy and provide inputs for calculating thecost effectiveness of new policies and interventions.Internationally, there have been several studies estimatingthe cost of or loss of health-related quality of life from NTSillness, demonstrating that NTS has a substantial economicburden (25, 29, 38, 40). Although the overall cost offoodborne disease in Australia circa 2000 was estimated atAUD 1.2 billion (1), the costs were not assessed at apathogen level. Given the burden of salmonellosis in
* Author for correspondence. Tel: þ61 2 6125 2468; Fax: þ61 2 61250270; E-mail: kathryn.glass@anu.edu.au.
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Australia, our aim was to provide contemporary estimatesof the cost of illness associated with NTS and resultingsequelae (IBS and ReA) in Australia circa 2015.
MATERIALS AND METHODS
We estimated costs of NTS illness and resulting sequelaeillnesses in @Risk (http://www.palisade.com) by using directhealth care costs, productivity loss, and the value of prematuremortality for acute and ongoing illness. The estimated directand indirect costs were based on the incidence of NTS, IBS,and ReA illness and ongoing illness from IBS and ReA in atypical year circa 2015. We estimated incidence and costs byfour age groups: 0 to 4 years, 5 to 19 years, 20 to 64 years, and65þ years. Data sources and model structure are describedbelow with additional information in Supplemental Material S1and S2.
Data sources for incidence burden estimates. We used datafrom the National Notifiable Disease Surveillance System by sexand 5-year age groups from 2013 to 2015 (12). Notificationswhere age, sex, or both were unknown were excluded (0.16%).Denominator data were based on the Australian populationprovided by the Australian Bureau of Statistics for that year (2).As IBS and ReA are rare in children ,5 years old (23, 39), weused the ratio of incidence to hospitalizations for IBS and ReA inthose aged 5 to 64 years to estimate incidence in children aged ,5years.
Data sources for health care usage burden estimates. ForNTS, we used data from the 2008 to 2009 National GastroenteritisSurvey II, a retrospective cross-sectional survey of the populationburden of infectious gastroenteritis in that year (8), to estimate theproportion of incident cases that consulted a general practitioner(GP), visited the emergency department, or took medication(antibiotics, diarrhea relief, pain relief, nausea relief, cramp relief).We weighted each of these proportions by the severity of diarrhea,with 1 to 2 days of diarrhea classified as mild disease, 3 to 4 daysas moderate, and 5 or more days as severe (Supplemental MaterialS1 and S2), and we assumed that 3% of NTS cases were mild,14% were moderate, and 83% were severe as in Hall et al. (21).The number of stool microscopy, culture, and sensitivity tests,stool PCR tests, or both were estimated from the median numberof notifications by age group in the National Disease SurveillanceSystem (12) from 2013 to 2015, all of which were confirmed bylaboratory testing (Supplemental Material S1). For IBS and ReA,we estimated the proportion of cases that see a GP, visit aspecialist, receive treatment, or undergo testing from the literatureor from expert clinical opinion (for details, see SupplementalMaterial S1 and S2). We made an a priori assumption there wouldbe no emergency department visits for IBS or ReA followingSalmonella infection.
We used hospital separation statistics and average length ofstay data by principal diagnoses for the financial years 2011 to2012, 2012 to 2013, and 2013 to 2014 from the AustralianInstitute of Health and Welfare to estimate NTS, IBS, and ReAhospitalizations (5, 6). Diagnostic codes were based on theAustralian modification of the 10th International Classification ofDiseases and are detailed in Technical Appendix 3 of Kirk et al.(28) and Technical Appendix 4 of Ford et al. (18). Becauseprincipal diagnosis data only are available online from theAustralian Institute of Health and Welfare, we imputed thenumber of additional diagnoses for NTS, IBS, and ReA based onKirk et al. (28) and Ford et al. (18).
Data sources for lost productivity burden estimates. Daysof lost paid work for illness and caring were estimated from theNational Gastroenteritis Survey II for NTS. Using the sameapproach taken for GP and emergency department visits, weadjusted data on the number of reported days of paid work misseddue to gastroenteritis illness or caring for someone with agastroenteritis illness for the severity of diarrhea and by age group.We followed Abelson et al. (1) in estimating days of lost paidwork as days in hospital plus 0.5 day for visiting the GP for IBSand data from Townes et al. (42) to estimate a distribution of 3.37days (90% credible interval [CrI], 2.59 to 4.3) for ReA.Confidence intervals (CI) for days of lost paid work due toNTS, IBS, and ReA illness were generated using cii means with aPoisson distribution in Stata SE 14.2 (StataCorp LLC, CollegeStation, TX).
Data sources for premature mortality burden estimates.We used data from the Australian Bureau of Statistics onunderlying or contributing causes of death in males and femalesaged 0 to 14, 15 to 64, and 65þ years from 2001 to 2010. Thediagnostic code used was A02, based on the 10th InternationalClassification of Diseases as detailed in Technical Appendix 3 ofKirk et al. (28). We estimated the number of deaths due to NTSinfection for our age groups by using a statistical model withmultipliers for underreporting, domestic acquisition, and food-borne proportion, as in Kirk et al. (28). We assumed no prematuremortality due to IBS or ReA.
Data sources for ongoing illness burden estimates. Weused the literature and built on previous work (1) that wasreviewed and updated by an expert clinician, to estimate theproportion of cases that have ongoing illness from incident IBS orReA following Salmonella infection in a typical year circa 2015.For IBS, we estimated that 42.9% (95% CI, 21.8 to 66%) of caseswould have continuing symptoms at 12 months (31). For ReA, weestimated that 50% (95% CI, 23 to 77%) would have continuingsymptoms at 3 months (23, 30).
Data sources for health care usage cost estimates. Weassumed costs for GP and specialist visits based on the MedicareBenefits Schedule (9). We used an estimate from 2009 to 2010 inNew South Wales for emergency department triage costs (36),and hospital cost data were extracted as Australian RefinedDiagnosis Related Group costs published by the IndependentHospital Pricing Authority for 2013 to 2014 (26). Becausepathology costs are generally paid for through national healthinsurance, we calculated the costs by dividing total benefits(monetary value spent) by services (number billed) fromMedicare item reports (13) for Medicare Benefits Schedule (9)for relevant item numbers. Costs were extracted from thePharmaceutical Benefits Schedule by dividing total benefits byservices (pharmaceuticals) from Pharmaceutical Benefits Sched-ule item reports (14) for Pharmaceutical Benefits Schedule itemnumbers (10) for the calendar year 2015. If the medication ortreatment was not listed on the Pharmaceutical Benefits Scheduleor may commonly be bought over the counter, we extracted costsfrom an Australian pharmaceutical store (https://www.chemistwarehouse.com.au). See Supplementary Material S2 fordetails.
Data sources for lost productivity cost estimates. We useda human capital approach to calculate the cost of lost productivity(34) and tested lost productivity in sensitivity analysis. We usedthe participation rate in the workforce by age group for June 2015
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extracted from the Australian Bureau of Statistics (79.2% for 20 to64 years and 12.2% for 65 years and older) (3) and multiplied thisby the estimated days of lost paid work and by the daily wage rate.As the Australian Bureau of Statistics provided a participation ratefor 15- to 19-year-olds (52.6%), we weighted this across our 5- to19-year-old age group to produce a participation rate of 17.5%.We used the participation rate for 20- to 64-year-olds (79.2%) fordays of paid work missed by carers reported in the NationalGastroenteritis Survey II for the age groups 0 to 4 years, 5 to 19years, and 20 to 64 years and the participation rate for 65 years andolder (12.2%) for the age group 65þ years. To calculate the dailywage rate, we divided the average weekly earnings for May 2015extracted from the Australian Bureau of Statistics (4) by 5 toestimate a daily productivity cost of AUD 227.38.
Data sources for premature mortality cost estimates. Tocalculate mortality costs, we used a value of statistical life: ‘‘thefinancial value society places on reducing the average number ofdeaths by one’’ (24, 33). We used a 2014 value of statistical lifefrom the Australian Office of Best Practice Regulation (33),adjusted to 2015 dollars by using the Reserve Bank of Australiainflation calculator (37), of AUD 4,263,351.50.
Data sources for new ongoing illness cost estimates. Tocalculate the health care costs of new ongoing illness over 1 year,we used medication costs and specialist visit costs as describedabove. To calculate lost productivity costs from ongoing illnessover 1 year, we used the lost productivity cost as described above.
Burden estimates. We used the same estimation approach,distributions, and multipliers to estimate foodborne NTS, IBS, andReA incidences, hospitalizations, and deaths as in the foodbornedisease estimation study circa 2010 (18, 28). We used simulationtechniques in @Risk for each estimate using multiple inputs, eachwith a level of uncertainty for our four age groups. The finaloutput was a distribution, from which we extracted a medianestimate of incidence, hospitalizations, and deaths together with90% CrI. Because mortality data were only available for 2000 to2010, we added an additional step to these models that multipliedthe estimated median rate of foodborne illness for NTS by thepopulation for 2013 to 2015. This adjusted the estimate forchanges in the population since 2000 to 2010, although it does notallow us to detect any change in the death rate since 2010. Moreinformation about distributions and outputs can be found inSupplemental Material S1.
Cost estimates. In @Risk, we multiplied burden estimates bycosts for health care, lost productivity, and valuation of prematuremortality for each age group and for all cases to calculate costs inAUD value for health care usage, the loss to productivity, and theimplied value of life. From the resulting distribution, we extracteda median, mean, and 90% CrI. We used an expert elicitation of theproportion of foodborne NTS infections (43) to estimate the costof NTS, IBS, and ReA due to contaminated food.
Sensitivity analyses. We used a probabilistic simulationapproach by calculating 90% CrI for key parameters known tovary in our burden estimates. We also conducted a one-waysensitivity analysis by halving and doubling individually firsthealth care usage costs and then productivity costs and finally thevalue of statistical life values (15). In addition, because estimatingthe net present value of production changes is difficult (11), wetested the impact of removing all productivity losses from acuteillness and used an alternative participation rate to model the
probability that both parents of 0- to 4-year-olds and 5- to 19-year-olds are working (0.627) in calculating lost productivity due tocaring. Because approximately 75% of 15- to 19-year-olds are inthe labor force part-time (2) and a day of missed paid work maynot be the equivalent of a full-time day, we also performed asensitivity analysis of halving the daily wage rate for this group.
RESULTS
Estimated burden of NTS in Australia. We estimated90,833 (90% CrI, 51,583 to 158,265) cases, 4,312 (90% CrI,3,335 to 11,091) hospitalizations, and 19 (90% CrI, 15 to22) deaths from salmonellosis in Australia circa 2015 (Table1). Of these, 64,000 (90% CrI, 34,000 to 117,000) cases,3,100 (90% CrI, 1,829 to 4,786) hospitalizations, and 13(90% CrI, 10 to 17) deaths were estimated to be due tocontaminated food.
Estimated costs of NTS disease. We estimate thatNTS cost a median of AUD 124.4 million and a mean of124.7 million (90% CrI, 107.4 to 143.1 million) circa 2015,with a median of 23.7 million and a mean of 23.8 million(90% CrI, 19.3 to 28.9 million) from health care usage, amedian of 21.3 million and a mean of 22.0 million (90%CrI, 13.7 to 32.6 million) from lost productivity, and amedian and mean of 79.0 million (90% CrI, 66.0 to 92.1million) from premature mortality. When acute andongoing illness from IBS and ReA following Salmonellainfection were included, the estimated cost was a median ofAUD 146.8 million and a mean of 147.2 million (90% CrI,127.8 to 167.9 million) (Table 2 and Supplemental MaterialS3). NTS illness due to contaminated food was responsiblefor a median of AUD 88.9 million and a mean of 88.7million (90% CrI, 63.9 to 112.4 million) of the total cost ofNTS illness and a median of AUD 104.8 million and amean of 104.6 (90% CrI, 75.5 to 132.3 million) when IBSand ReA were included. Premature mortality from NTS asthe underlying or contributing cause of death was thehighest contributor to the total cost, accounting for 63% ofthe NTS cost and 54% of the total cost. Lost productivitydue to acute NTS infection accounted for 17% of the NTScost, lost productivity due to acute and ongoing IBSaccounted for 39% of the IBS cost, and lost productivityfrom acute and ongoing ReA accounted for 59% of the ReAcost.
The total cost of illness and the total cost per case washighest in the 65þ years age group (Tables 3 and 4;Supplemental Material S3 for means). Overall, we estimat-ed that the cost of acute salmonellosis was a median ofAUD 1,322 per case and AUD 1,559 per case when IBS andReA were considered (Table 4; Supplemental Material S3for means).
Sensitivity analysis. In probabilistic simulation of theburden estimate parameters, uncertainty was greatest inpremature mortality, followed by estimates of lost produc-tivity (Fig. 1).
In one-way sensitivity analyses of costs, varying valueof statistical life for premature mortality costs by halvingand doubling costs had the largest impact on cost values
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(Fig. 2). Additional sensitivity analysis showed thatremoving costs associated with short-term productivity lossfrom acute NTS, IBS, and ReA illness resulted in an AUD21.1 million drop in the NTS cost to 102.7 million (90%CrI, 89.0 to 116.8 million) and an AUD 26.5 million drop inthe total cost estimate to 119.8 million (90% CrI, 104.7 to135.7 million). Adjusting the participation rate of carers for0- to 4-year-olds and for 5- to 19-year-olds, and halving thedaily wage for 5- to 19-year-olds had a minimal impact onthe final cost estimates, reducing the estimate by less than2% and less than 1%, respectively.
DISCUSSION
We estimated that the burden of salmonellosis and itssequelae in Australia are substantial, costing a median ofAUD 146.8 million in a typical year circa 2015. Of the totalcost, 35.7 million (24%) was due to health care costs, 31.7million (22%) was due to costs associated with lostproductivity, and 79.0 million (54%) was due to prematuremortality. Quantifying these costs allows the burden of NTSto be compared against other illnesses, assisting withprioritization of public health interventions for policy-making.
TABLE 1. Estimated median number of cases, hospitalizations, and deaths from NTS and resulting IBS and ReA circa 2015, Australia
Median no. (90% CrI)
NTS IBS ReA
Cases
0–4 yr 20,924 (12,059–36,250) 1.46 (0.82–2.57) 341 (56–898)5–19 yr 14,617 (8,408–25,384) 1,284 (714–2,308) 1,206 (290–3,125)20–64 yr 44,525 (25,012–77,489) 3,906 (2,104–7,077) 3,652 (865–9,626)65þ yr 10,767 (6,104–19,042) 942 (516–1,703) 881 (209–2,310)
Total 90,833 (51,583–158,165) 6,133 (3,335–11,091) 6,080 (1,420–15,959)
Hospitalizations
0–4 yr 984 (661–1,346) 0.29 (0–0.23) 1.84 (1.07–3.52)5–19 yr 607 (391–912) 16 (9–25) 4 (3–6)20–64 yr 1,814 (1,162–2,750) 326 (186–517) 20 (13–26)65þ yr 907 (570–1,382) 67 (39–104) 2.5 (2–4)
Total 4,312 (2,784–6,390) 409 (234–647) 28 (19–40)
Deaths
0–4 yr 0.65 (0.5–0.82) —a —5–19 yr 1.7 (1.34–2.07) — —20–64 yr 4 (2.71–4.38) — —65þ yr 13 (10–15) — —
Total 19 (15–22) — —
a —, not applicable.
TABLE 2. Estimated annual cost of illness of health care usage, lost productivity, and premature mortality, for acute and ongoing illness,circa 2015, Australia
Median cost in millions of AUD (90% CrI)
NTS IBS ReA Totala
Health care usage
Acute illness 23.7 (19.3–28.9) 5.6 (4.0–8.0) 1.9 (1.0–3.6) 31.4 (26.5–37.2)Ongoing illness —b 3.2 (1.8–6.9) 0.77 (0.34–1.7) 4.2 (2.7–6.5)
Lost productivity
Acute illness 21.3 (13.7–32.6) 2.0 (1.3–3.3) 2.7 (1.0–6.5) 26.5 (18.5–38.4)Ongoing illness — 3.6 (1.8–6.9) 1.0 (0.37–2.8) 4.8 (2.7–8.4)
Premature mortality
Acute illness 79.0 (66.0–92.1) — — 79.0 (66.0–92.1)
Total costs
Acute illness 124.4 (107.4–143.1) 7.6 (5.3–11.3) 4.6 (2.0–10.0) 137.7 (119.7–157.0)Ongoing illness — 6.8 (3.9–12.3) 1.8 (0.73–4.4) 9.0 (5.5–14.8)
Total 124.7 (107.4–143.1) 14.5 (9.5–23.0) 6.5 (2.8–14.2) 146.8 (127.8–167.9)
a Numbers may not sum due to simulation and rounding.b —, not applicable.
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Because NTS is mostly transmitted through contami-nated food, targeted interventions across the food chaincould help to prevent acute and ongoing illness. Australia’sFoodborne Illness Reduction Strategy 2018 to 2021þ aimsto reduce the number of illnesses from foodborne
salmonellosis (17). Although the national strategy doesnot set a specific reduction target, a 10% reduction in acutefoodborne NTS illness incidence would equate to more thanAUD 8 million immediate reduction in costs, withadditional reductions from sequel illnesses expected as well.
Because of the higher proportion of people aged 65þyears with salmonellosis taking medications, being admittedto the hospital, and dying compared with other age groups,the cost per case was highest in the 65þ age group.Therefore, interventions targeted at preventing illness in thisage group would be most effective in reducing all costs. Our
TABLE 3. Estimated annual cost of acute and ongoing illness in 1 yr by age group, circa 2015, Australia
Median cost in millions of AUD (90% CrI)
NTS IBS ReA Totala
Health care usage
0–4 yr 4.2 (3.0–5.9) 0.004 (0.002–0.006) 0.14 (0.04–0.37) 4.4 (3.2–6.1)5–19 yr 2.8 (2.0–4.0) 1.6 (0.90–3.0) 0.48 (0.13–1.3) 5.1 (3.7–6.9)20–64 yr 8.6 (5.9–12.4) 5.7 (3.3–9.8) 1.5 (0.46–4.0) 16.3 (11.9–22.0)65þ yr 7.6 (5.1–11.0) 1.4 (0.80–2.4) 0.34 (0.10–0.93) 9.4 (6.8–13.0)
Lost productivity
0–4 yr 4.9 (2.3–10.0) 0.002 (0.001–0.004) 0.29 (0.07–0.78) 5.2 (2.6–10.3)5–19 yr 1.5 (0.46–4.4) 0.34 (0.17–0.65) 0.23 (0.05–0.61) 2.2 (1.0–5.0)20–64 yr 12.6 (6.7–22.8) 5.0 (2.7–9.4) 3.1 (0.73–8.4) 21.7 (13.9–33.6)65þ yr 1.2 (0.33–3.0) 0.18 (0.10–0.35) 0.11 (0.03–0.31) 1.5 (0.64–3.3)
Premature mortality
0–4 yr 2.8 (2.1–3.5) —b — 2.8 (2.1–3.5)5–19 yr 7.2 (5.7–8.8) — — 7.2 (5.7–8.8)20–64 yr 15.0 (11.6–18.7) — — 15.0 (11.6–18.7)65þ yr 53.8 (41.6–66.3) — — 53.8 (41.6–66.3)
Total costs
0–4 yr 11.9 (8.5–18.1) 0.006 (0.004–0.009) 0.43 (0.11–1.1) 12.4 (8.9–18.6)5–19 yr 11.8 (9.4–15.3) 2.0 (1.1–3.6) 0.70 (0.09–1.9) 14.7 (11.9–18.6)20–64 yr 36.5 (27.7–49.8) 10.7 (6.0–19.1) 4.6 (1.2–12.2) 53.3 (41.2–70.0)65þ yr 62.9 (50.3–75.9) 1.5 (0.9–2.7) 0.46 (0.12–1.2) 65.2 (52.5–78.2)
a Numbers may not sum due to simulation and rounding.b —, not applicable.
TABLE 4. Estimated median annual cost of acute and ongoingillness per case by age group, circa 2015, Australia
Median cost (AUD)
NTS IBS ReA Total
Health care usage only
0–4 yr 200.78 854.05 302.90 208.655–19 yr 190.85 434.31 287.48 344.3320–64 yr 192.17 491.17 301.1 363.4965þ yr 691.93 491.80 284.09 866.14
Total 250.02 476.64 293.32 377.97
Health care usage with lost productivity
0–4 yr 443.64 1,398.50 920.24 467.785–19 yr 307.88 525.02 423.95 507.5620–64 yr 480.79 930.31 916.21 845.7865þ yr 814.92 558.66 378.88 1,020.85
Total 479.99 783.99 718.10 713.85
Health care usage, lost productivity, and premature mortality
0–4 yr 579.88 1,398.50 920.24 603.975–19 yr 807.77 525.02 423.95 1,003.8820–64 yr 818.47 930.31 916.21 1,190.3565þ yr 5,798.29 558.66 378.88 6,003.72
Total 1,322.14 783.36 718.96 1,558.53
FIGURE 1. Median cost of acute and ongoing illness from NTS,IBS, and ReA from health care usage, lost productivity, andpremature mortality, circa 2015, Australia. Ranges reflect 90%credible intervals for burden estimates.
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total cost per case for NTS of AUD 1,322 (~USD 995) isgenerally lower than in studies from the United States from2013 and 2015 (USD 3,568 (16), USD 5,335 (32)), althoughhigher than an estimate of E691 (~USD 765) by Sundstrom(40) for Sweden in 2016 dollars and the estimate of NZD220 (~USD 151) by Lake et al. (29) for New Zealand in2006 and 2007. The estimates from these studies are notdirectly comparable due to differing years, variablesestimated, and estimation methods.
Because premature mortality from NTS as the under-lying or contributing cause of death was the largestcontributor to our cost estimates, accounting for 63% oftotal NTS cost and 54% of NTS and sequelae cost, themethod used to value a lost life is very influential. In one-way sensitivity analysis, premature mortality costs had thelargest range of uncertainty, compared with health careusage and lost productivity costs. Methods and values forlost life are also influential when comparing estimatesbetween cost-of-illness studies. For example, although thetotal cost per NTS case estimated by the EconomicResearch Service for the United States is higher than ourestimate at USD 3,568, when only costs from health careusage and lost productivity are taken into account, the costestimates are similar at USD 383.55 for the United Statescompared with our estimate of AUD 480 (~USD 361) (16).
Costs associated with IBS and ReA following Salmo-nella were also a large contributor to our total cost estimateof AUD 146.8 million, accounting for 14% of the total cost(10% from IBS and 4% from ReA). Although we didaccount for these sequelae costs in our estimates, we havenot included costs of NTS to industry and public healthagencies for surveillance and regulation. Because NTS canbe expensive for the food industry, including costsassociated with everyday prevention measures, productrecalls, and liability, we have likely underestimated thecosts to society.
Although we estimated lost productivity costs in linewith previously published methods (1), these methods mayoverestimate costs as we have not considered that either
production will be made upon return to work or thatemployers will have excess capacity in the labor force tocover absenteeism for short-term absences (11). Inaddition, a weakness of the human capital approach isthat it overestimates productivity loss compared with thefriction cost approach (34). We restricted lost productivityestimates to paid work only, not including the value of losttime for those not employed, such as unpaid carers orhousework, or the loss of leisure time. One-way sensitivityanalysis of removing productivity loss from acute illnessresulted in a AUD 21.1 million reduction in the estimatefor NTS and a AUD 26.5 million reduction for NTS, IBS,and ReA.
A limitation of this study is that due to a lack of data forIBS and ReA, we relied on expert opinion from a physicianto review and update the proportion of cases receivingcertain medications, pathology tests, and IBS cases seeingspecialists from previous work and the literature. We useduncertainty intervals around these estimates to account forthe uncertainty in the data. There is also limited data onduration of ongoing ReA symptoms, with some studiesfinding that symptoms had ceased in most patients in lessthan 12 months (22, 23, 30), whereas others found caseswith long-lasting symptoms (19, 41). We used a conserva-tive estimate of the proportion of ReA cases with ongoingsymptoms in 1 year based on Hannu et al. (23) andLeirisalo-Repo et al. (30). Although we were not able toinclude the decrease in quality of life to calculate qualityadjusted life years, we have captured the decrease inquantity of life through the value of statistical life. Althoughour cost of illness estimates provide a baseline, a fulleconomic evaluation that compares costs and benefits ofalternative policy interventions is needed to identify howeffective new programs and policies would be at reducingburden. Identifying and implementing targeted preventionmeasures in the food supply chain could considerablyreduce overall NTS costs.
In summary, the clinical and economic burden ofsalmonellosis and its sequelae are high. The cost of illnessestimates in this article will inform food safety policy andcan be used in subsequent analysis of cost effectiveness ofnew policies and interventions aimed at the prevention andcontrol of NTS infection in Australia.
ACKNOWLEDGMENTS
L. Ford is supported by an Australian Government Research TrainingProgram scholarship. M. D. Kirk is supported by a National Health andMedical Research Council fellowship (APP1145997). D. A. Williamson issupported by a National Health & Medical Research Council fellowship(APP1123854).
SUPPLEMENTAL MATERIAL
Supplemental material associated with this article can befound online at: https://doi.org/10.4315/0362-028X.JFP-19-105.s1https://doi.org/10.4315/0362-028X.JFP-19-105.s2, and https://doi.org/10.4315/0362-028X.JFP-19-105.s3
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46
Cost of whole genome sequencing for non-typhoidal Salmonella enterica
Laura Ford, Kathryn Glass, Deborah A. Williamson, Vitali Sintchenko, Jennifer M.B. Robson,
Russell Stafford, Martyn D. Kirk
ABSTRACT
Rapidly changing technology for testing and typing non-typhoidal Salmonella enterica has
significant implications for public health surveillance. We examined the costs of whole genome
sequencing (WGS) in Australia compared to traditional testing, which is required to assist
public health action to prevent illness. We used laboratory testing and Salmonella case costs
to determine how many cases the use of WGS data would need to prevent to be cost-equal to
serotyping and multiple locus variable number tandem repeat analysis, or culture independent
testing based on polymerase chain reaction (PCR). We then examined the costs and cost-
savings of using current typing methods compared with WGS in outbreak scenarios. A median
of 275 (90% CrI -55-775) or 1.9% (90% CrI -0.4%-5.4%) of notified serotyped Salmonella
cases would need to be prevented for WGS to be cost-equal to current typing methods and
1,550 (90% CrI 820-2,725) or 9.6% of all notified Salmonella cases would need to be prevented
to be cost-equal to PCR. WGS has different cost effects in different outbreak scenarios, but
WGS data would result in cost savings in prolonged outbreaks if it helped public health action
occur earlier. Despite currently having a higher cost per isolate, routine WGS of Salmonella
will be no more expensive than existing typing methods or PCR if it can help avert illness.
INTRODUCTION
Culturing human samples for non-typhoidal Salmonella enterica informs both clinical diagnosis
and public health surveillance. Routine epidemiological typing of cultured Salmonella isolates
allows health agencies to identify outbreaks and sources of infection, and implement control
measures to prevent further illness. Conventional typing methods, such as serotyping, pulse
field gel electrophoresis (PFGE), and multiple locus variable-number tandem repeat analysis
(MLVA) may differentiate Salmonella cases for surveillance and outbreak detection, helping to
save lives and reduce costs to human health and industry (Ross et al. 2011; Scharff et al.
2016).
New technologies for laboratory testing and typing Salmonella are moving in divergent
directions. The emergence of culture-independent diagnostic testing through Polymerase
Chain Reaction (PCR) assays allows for quick, sensitive and inexpensive Salmonella
detection, compared with conventional culture on selective media. However, unless reflexive
culture (i.e. culture on PCR-positive samples) is performed, no isolate is grown and available
47
for typing. PCR tests alone provide limited information for public health surveillance. This
delays the recognition of outbreaks, potentially leading to larger outbreaks and increased
societal costs (Cronquist et al. 2012).
If an isolate is cultured, whole genome sequencing (WGS) has emerged as an alternative to
conventional typing methods such as serotyping and MLVA. WGS generates highly
discriminatory data on Salmonella isolates for surveillance and outbreak detection (Deng et al.
2016). WGS has been shown to help detect outbreaks while they are still small and to link food
sources to outbreaks, allowing for quick and effective intervention and control (Jackson et al.
2016). However, at present, public health and laboratory infrastructure required to adopt WGS
and sequencing costs can be high.
Although sequencing costs are declining, WGS of foodborne bacterial pathogens is currently
still more expensive than PCR and the cost differential with conventional typing methods
varies. In Australia, once a patient submits a clinical sample to a laboratory, Salmonella can
either be detected (with PCR) or isolated from that sample. If isolated, several typing methods
can be employed to characterise the isolate for public health surveillance and outbreak
investigation (Figure 1). We argue that WGS could reduce the societal costs of Salmonella if
it can reduce the number of people affected, and the costs of these affected cases are
considered. We examined the societal costs of three Salmonella testing and typing approaches
in terms of how they assist public action to detect outbreaks, implement control measures, and
prevent cases in Australia: (1) the current standard of culture, serotyping and MLVA; (2) culture
and WGS; and (3) PCR testing.
METHODS
Figure 1 highlights the three methods for which we have examined costs. We have not costed
PCR followed by reflexive culture, as this will always be more expensive than PCR or culture
alone. Costs and cost savings are reported in 2018 US dollars (USD), with Australian dollars
(AUD) converted to USD using the average monthly exchange rate from Jan-Jun 2018 of
0.7676 from the Reserve Bank of Australia (Reserve Bank of Australia 2018a) and inflation
adjusted for using the Reserve Bank of Australia’s inflation calculator (Reserve Bank of
Australia 2018b). To assess costs, we first determined how many cases must be prevented
for each method to be cost-equal to serotyping and MLVA, and then modelled outbreak
scenarios with different intervention points based on test data to assess cost savings.
Data sources
We used a cost per Salmonella case circa 2015 from Ford et al (forthcoming) including direct
and indirect costs of health care usage, lost productivity, and premature mortality from acute
48
infection, adjusted for inflation to 2018. We removed testing costs from the cost per case to
enable comparison of the three testing and typing regimes. Salmonella notification numbers
from 2017 were obtained from the National Notifiable Diseases Surveillance System (NNDSS)
(Department of Health 2018b). As 35% of notifications in Australia are serotyped as S.
Typhimurium (Supplementary information) and subsequently undergo multiple variable
number tandem repeat analysis (MLVA) (Ford et al. 2016), we separated Salmonella
Typhimurium and non-Typhimurium Salmonella. We used the mean and range of costs for
serotyping, MLVA (S. Typhimurium), and WGS (where available) collected from each of the 5
Australian state public health reference laboratories in mid-2018. For culture and PCR test
costs, we calculated cost per test by dividing the total benefits (monetary value spent) by the
number of services (number billed) of item reports 69345 and 69496 respectively in the
Medicare Benefits Schedule for the financial year 2017/18 (Department of Health 2018a;
Department of Human Services 2018). This resulted in a cost of USD 34.70 for PCR and USD
40.61 for culture. To model cost savings in an outbreak scenario, we used simulated data
based on Australian Salmonella outbreak data (Denehy et al. 2011; Todd 2018).
Figure 1: Flow chart of testing and typing methods for Salmonella in Australia
Analysis
Cases prevented
We calculated how many cases WGS data would have to prevent before it would cost the
Australian society no more than serotyping and MLVA. As it is difficult to detect outbreaks with
PCR, leading to delays in implementing control measures and potentially larger outbreaks
(Cronquist et al. 2012), we also used the same analysis to calculate how many cases WGS
49
and the status quo would have to prevent before they cost no more than PCR. The equation
to determine the threshold is given by:
In addition, to examine the effects of changes in WGS costs, we calculated how much the price
would have to drop before WGS was cost equal with (1) serotyping and (2) PCR. We performed
these analyses in @Risk version 6 (http://www.palisade.com). Uncertainty intervals for
Australia were generated from the minimum and maximum cost estimate for serotyping, MLVA,
and WGS from the reference laboratories. We used a PERT distribution for cost estimates with
uncertainty to generate median and 90% credible intervals for the number and proportion of
cases that need to be prevented, as well as the WGS cost decrease needed, for tests to be
cost neutral.
Outbreak scenario
The costs of using the testing and typing regimes were examined in three simulated
community outbreak scenarios: (1) a point source outbreak, (2) a prolonged outbreak with no
peak, and (3) a prolonged outbreak with a late peak. We sourced mean case numbers from
Australian Salmonella outbreak data (Denehy et al. 2011; Todd 2018) to generate random
daily case numbers sampled from a Poisson distribution for each outbreak scenario. We
estimated the cost of the outbreak using the cost per case and the costs per test as described
above. With Microsoft Excel and @Risk, we calculated the cost differences if WGS was used
in all three scenarios, and if a product recall or intervention occurred at an earlier time point
along the epidemiological curve (30, 60, and 90 days earlier) of the prolonged outbreak
scenarios using WGS. While it is unlikely that outbreaks would have the same epidemiological
curve if all human samples were only tested by PCR, we have considered outbreak costs using
PCR testing in these scenarios for comparison. We compared characteristics of our outbreak
scenario models with real Australian salmonellosis outbreak data from Queensland Health
(see Supplementary Information).
RESULTS
In 2018 in Australia, reference laboratories reported that the mean cost for serotyping
Salmonella was USD 42.37 (range USD 13.82-75.22), while MLVA cost USD 52.66 (range
USD 24.56-95.95) and WGS cost USD 83.15 (range USD 72.92-95.95). The cost per case of
Salmonella spp. infection was USD 1,098 (90% CrI USD 623-1,963).
50
We estimated that approximately 365 (90% CrI 145-775) or 4.2% of non-Typhimurium
Salmonella spp. cases needed to be prevented in Australia in a year for WGS to be cost-equal
to serotyping, at current costs (Table 1). Serotyping and MLVA for S. Typhimurium was more
expensive than WGS, meaning that WGS is already less expensive than current methods for
S. Typhimurium.
Table 1: Number of cases that need to be prevented in order for WGS and PCR methods to be cost-equal to current methods, Australia, 2018
Salmonella Typhimurium Non-Typhimurium Salmonella Median cases
(90% CrI) %
(90% CrI) Median cases
(90% CrI) %
(90% CrI) WGS vs current methods*
-80 (-325-100) -1.4 (-5.6-1.7) 365 (145-775) 365 (145-775)
Current methods* vs PCR
390 (170-790) 6.8 (3.0-13.9) 80 (-115-340) 0.9 (-1.3-3.9)
*Current methods are serotyping and MLVA (if serotyped as Salmonella Typhimurium)
Combining S. Typhimurium and non-Typhimurium cases, 275 (90% CrI -55-775) or 1.9% (90%
CrI -0.4%-5.4%) of all notified serotyped Salmonella cases needed to be prevented for WGS
to be cost-equal to serotyping and MLVA. For WGS to be cost-equal to PCR, 1,550 (90% CrI
820-2,725) or 9.6% (90% CrI 5.1%-17%) of Salmonella spp. cases need to be prevented in a
year.
If WGS costs dropped a median of USD 40.65 (95% CrI USD 20.00-60.73), or approximately
33%, then WGS would be cost-equal to serotyping with current case numbers. The costs would
need to drop by a median of USD 89.39 (95% CrI USD 82.53-96.79), or approximately 72% to
be cost-equal to PCR with current case numbers.
Outbreak scenarios
Point source outbreak
As exposure during a point source salmonellosis outbreak tends to occur over a relatively short
period (e.g. 1 meal), we used a conservative assumption that interventions will have no effect
on reducing case numbers in that outbreak. Therefore, detecting the outbreak sooner through
WGS would have no effect on reducing those outbreak costs. In our point source outbreak
scenario, there were 31 cases, with illness onsets occurring over 7 days (Figure 2). We
estimated the cumulative costs of the outbreak with PCR at USD 35,102 (90% CrI 20,222-
61,847), culture and serotyping at USD 36,648 (90% CrI 21,750-63,489), with WGS at USD
37,851 (90% CrI 23,019-64,699) (USD 1,203 more than culture and serotyping), and with
51
culture, serotyping, and MLVA at USD 38,369 (90% CrI 23,416-65,082) (USD 518 more than
WGS) (Figure 2).
Prolonged outbreak, no peak
We simulated a prolonged salmonellosis outbreak lasting 150 days, with a mean daily case
number of 1.5 cases for the first 120 days, and assuming an intervention was put in place at
120 days with a mean daily case number of 0.2 cases for the last 30 days. In this outbreak
scenario, there were 174 cases, with a cumulative cost of USD 205,808 (90% CrI 121,842-
352,912) using culture and serotyping, USD 212,807 (90% CrI 129,134-360,199) using WGS
(Figure 2), and USD 215,587 (90% CrI 131,564-362,438) using culture, serotyping and MLVA.
While an outbreak like this may not be detected if all samples were PCR-only, if it were
detected with the same epidemiological curve, we estimated a cumulative cost of USD 197,117
(113,315-344,546) using PCR (Figure 2). If WGS enabled early detection such that the
intervention was put in place 30 days earlier, this would result in a savings of USD 34,359
(90% CrI 14,606-68,792) over PCR or USD 42,814 (90% CrI 22,756-77,399) over culture and
serotyping, rising to a savings of USD 97,112 (90% CrI 52,167-174,489) over PCR or USD
105,057 (90% CrI 60,323-183,673) over culture and serotyping if the intervention was 60 days
earlier, and USD 138,783 (90% CrI 77,197-244,690) over PCR or USD 146,711 (90% CrI
85,408-254,676) over culture and serotyping if the intervention was 90 days earlier (Figure 2).
Prolonged outbreak, late peak
We simulated a prolonged salmonellosis outbreak based on real outbreak data lasting 180
days, with a 1 week peak occurring approximately 120 days after the start of the outbreak
(Todd 2018). We assumed a mean daily case number of 1.35 cases for the first 120 days, 4.5
cases for 7 days, 13.23 cases for 7 days, 2.25 cases for 7 days, and 0.14 cases for the last 39
days. We assumed an intervention was put in place at 140 days, following the peak. In this
outbreak scenario, there were 322 cases, with a cumulative cost USD 329,186 (90% CrI
194,382-575,442) using culture and serotyping, USD 340,759 (90% CrI 206,014-586,903)
using WGS (Figure 2), and USD 344,359 (90% CrI 209,629-590,760) using culture, serotyping
and MLVA. Again, while an outbreak like this may not be detected if all samples were PCR-
only, with the same epidemiological curve, we estimated a cumulative cost of USD 315,846
(90% CrI 181,015-561,523) using PCR (Figure 2). If WGS were able to detect the outbreak or
food vehicle earlier, this would result in a savings of USD 119,224 (90% CrI 62,199-223,053)
52
Figure 2: Epidemiological curve and cumulative outbreak case costs in simulated point-source
outbreak. Confidence intervals omitted for visual clarity.
53
over PCR or USD 132,739 (90% CrI over culture and serotyping if the intervention as put in
place 30 days earlier, USD 171,771 (90% CrI 93,859-313,571) over PCR or USD 185,042
(90% CrI 107,353-326,844) over culture and serotyping if the intervention was put in place 60
days earlier, and USD 225,469 (90% CrI 126,201-405,909) over PCR or USD 238,848 (90%
CrI 139,689-419,376) over culture and serotyping if the intervention was put in place 90 days
earlier (Figure 2).
DISCUSSION
In this study, we examined costs of three Salmonella testing and typing systems in Australia
in 2018 in terms of how they assist public health action. We found that WGS data needs to
prevent approximately 2% of all notifications currently serotyped, or approximately 10% of all
notifications if they were only tested through PCR to be cost-equal to current testing and typing
methods and PCR respectively. WGS could also significantly reduce costs in prolonged
outbreaks if the data helps public health officials to implement interventions earlier. Even in
point source outbreaks, where WGS is potentially least effective at reducing costs, by linking
multiple point source outbreaks or linking a specific food or food preparation practice to illness,
WGS data could help to avert future cases and reduce costs. Our findings present a compelling
case for widespread adoption of WGS in public health reference laboratories in Australia for
Salmonella surveillance and investigation, and can inform on the capacity of WGS for public
health globally.
As there are few examples in the literature of prospective use of WGS for surveillance and
outbreak detection, the effectiveness of preventing foodborne illness and the average time
from outbreak detection to the implementation of control measures is largely unknown.
However, there is evidence that compared to current Salmonella typing methods, WGS data
is more sensitive and specific in linking salmonellosis cases, helps link cases over wide
geographical areas and long time frames, reveals geographically distinct clusters,
differentiates cases not in an outbreak, results in better detection of Salmonella in food sources
and faster source tracking, and can provide evidence for the implementation of Salmonella
control plans in the food industry (Allard et al. 2018; Angelo et al. 2015; Bell et al. 2016; Ford
et al. 2018a; Ford et al. 2018b; Inns et al. 2017; Luna et al. 2018; Siira et al. 2019; Ung et al.
2019; Waldram et al. 2018). All of these advancements could lead to earlier intervention and
support more targeted use of public health resources, therefore reducing costs. In the USA,
PulseNet, a molecular subtyping network of federal, state, and local public health laboratories
has demonstrated significant economic and public health benefits through averting foodborne
illness with PFGE (Scharff et al. 2016), benefits which will likely be increased through the use
of WGS. A recent Canadian study estimated that WGS will result in a net benefit of $5.21
54
million for reported salmonellosis cases, $64.98 million if there is a 50% reduction of illness, or
$90.25 million if there is a 70% reduction in illness through the reduction of direct and indirect
salmonellosis costs from contamination in fresh produce, poultry, and eggs (Jain et al. 2019).
We have not addressed the costs of PCR and reflexive culture for all human samples in this
study, instead examining only costs associated with Salmonella positive samples first detected
either by PCR or culture. While PCR-only testing remains the cheapest option at present in
terms of raw costs, it results in a loss of subtyping capability (Cronquist et al. 2012), making
outbreak detection and linking human Salmonella infections to specific sources impossible.
Therefore, while we estimated PCR costs in our outbreak scenarios, it is likely that outbreak
epidemiological curves would be much larger, resulting in higher costs over other testing and
typing methods. In Australia, the large majority of Salmonella human isolates are still cultured,
either in the first instance or reflexively. Since the introduction of the multiplex PCR test in late
2013, the proportion of notifications without a serotype has increased from around 2% annually
(2009–2012) to 10% in 2017 (Department of Health 2018b). Although some of these may have
been PCR detections that were not reflexively cultured, it may also be a reflection of the
increased sensitivity of PCR over culture (Vohra 2019). A study in one Australian state found
that in 2014, while 6% of Salmonella notifications were diagnosed only by PCR test, a further
12% were PCR positive, but culture negative (May et al. 2017).
In this study, we assumed that WGS data will be received prospectively by the public health
departments in a timely, and standardized format. The harmonisation of WGS and
bioinformatic methods, terminology, and reporting across public health laboratories is essential
for public health surveillance and outbreak detection nationally (Williamson et al. 2019; World
Health Organization 2018). The ability to link Salmonella isolates from humans, foods, water,
animals, and the environment through standardized WGS data across states, regions, and
even globally will be key to using WGS data effectively to prevent cases.
Several limitations of this study have to be acknowledged. First, only per-isolate sequencing
costs were taken into account; we did not consider laboratory expenditures associated with
the transition to WGS. However, WGS costs have declined over time (World Health
Organization 2018) and this trend will likely continue as WGS replaces existing typing
techniques for foodborne pathogens. The Salmonella case cost estimate used here focuses
on healthcare expenditure and lost productivity, and does not include costs of Salmonella for
industry. The rapid detection of outbreaks can reduce costs for industry and trade, which we
have not accounted for in this study. Second, our analysis also does not take into account the
number of isolates required to fill a flow cell on the instrument and maximise the efficiency of
sequencing runs from a laboratory perspective. In lesser populated areas, waiting for a
55
sufficient number of isolates to complete a sequencing run or sending isolates away to other
public health reference laboratories may result in a delay in the public health department
receiving WGS data results, impacting the ability to implement timely public health action.
While laboratory subtyping data is an important component of Salmonella surveillance and
outbreak investigation, epidemiological and environmental investigation are also necessary for
the implementation of successful interventions. We acknowledge that there are other factors
in outbreaks besides laboratory typing data that may affect turn-around-time of WGS reporting.
Our approach could be applied to other pathogens to ascertain how many cases of infection
would need to be prevented before WGS was cost-equal to other methods. The models reflect
the monetary and non-monetary costs of disease outbreaks including the opportunity costs of
preventive interventions at the point of emergence. In the era of global trade and health
reforms, the added value of public health extends beyond national borders and strengthens
the economic imperatives for public health surveillance. Even though WGS currently has a
higher cost per isolate than serotyping for Salmonella in 2018 in Australia, WGS will be more
cost-effective if the genomic information can help prevent human infections by creating
opportunities for earlier public health action and identification of vehicles of infection. Currently
WGS for public health surveillance of Salmonella is dependent on culture either initially or
reflexively. However, there is significant research into metagenomics direct from faecal
specimens (Andersen and Hoorfar 2018; Besser 2018). Metagenomics has even been used
in a limited way to investigate foodborne disease outbreaks (Besser 2018). While waiting for
the costs of sequencing to decline and research in metagenomics to progress, the
effectiveness of WGS may actually reduce costs.
ACKNOWLEDGMENTS
We thank the state public health reference laboratories, Katherine Todd, and Queensland
Health for providing data. We also thank Emily Lancsar for her contribution.
Laura Ford is supported by an Australian Government Research Training Program (RTP)
Scholarship. Martyn D. Kirk is supported by a National Health & Medical Research Council
fellowship (APP1145997). Deborah A. Williamson is supported by a National Health & Medical
Research Council fellowship (APP1123854).
56
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59
Chapter 6. Impact of whole-genome sequencing on public
health surveillance of Salmonella Typhimurium
6.1 Introduction
In this chapter, I analyse data collected during 5 months of prospective sequencing of
Salmonella Typhimurium isolates from humans in the Australian Capital Territory. I investigate
the impact of phylogenomic Salmonella Typhimurium data on public health surveillance. The
chapter includes two peer-review papers, both published in Foodborne Pathogens and
Diseases. The first paper evaluates the performance of WGS for routine public health
surveillance, highlighting some challenges that should be addressed before routine
implementation. The findings of the evaluation show that phylogenomic data offers higher
discriminatory S. Typhimurium laboratory surveillance than existing methods.
The second paper reports on seven outbreaks across three states and territories that were
detected during the 5 months of sequencing of S. Typhimurium isolates in the ACT.
Phylogenomic data assisted in showing that isolates (both human and non-human) from the
seven outbreaks were related. This finding suggests that other outbreaks of S. Typhimurium
occurring across the country may be related and highlights the need for integrated national
surveillance as laboratories move towards routine WGS for non-typhoidal Salmonella
surveillance.
These two papers contribute to an improved understanding of the sources of infection of S.
Typhimurium and the implications of WGS for public health surveillance of non-typhoidal
Salmonella. Supplementary materials for these papers can be found in Appendix 4.
6.2 Papers
Ford L, Carter GP, Wang Q, Seemann T, Sintchenko V, Glass K, Williamson DA, Howard P,
Valcanis M, Castillo CFS, Sait M, Howden BP, Kirk MD. Incorporating whole-genome
sequencing into public health surveillance: lessons from prospective sequencing of Salmonella
Typhimurium in Australia. Foodborne Pathogens and Disease. 2018;15(3): 161-167, doi:
10.10189/fpd.2017.2352.
Ford L, Wang Q, Stafford R, Ressler KA, Norton S, Shadbolt C, Hope K, Franklin N, Krsteski
R, Carswell A, Carter GP, Seemann T, Howard P, Valcanis M, Castillo CFS, Bates J, Glass K,
Williamson DA, Sintchenko V, Howden BP, Kirk MD. Seven Salmonella Typhimurium
outbreaks in Australia linked by trace-back and whole-genome sequencing. Foodborne
Pathogens and Disease. 2018;15(5):285-292, doi: 10.1089/fpd.2017.2353
Incorporating Whole-Genome Sequencinginto Public Health Surveillance:
Lessons from Prospective Sequencingof Salmonella Typhimurium in Australia
Laura Ford,1,2 Glen P. Carter,3 Qinning Wang,4 Torsten Seemann,3 Vitali Sintchenko,4,5
Kathryn Glass,1 Deborah A. Williamson,3,6 Peter Howard,4 Mary Valcanis,6
Cristina Fabiola Sotomayor Castillo,4,5,7,8 Michelle Sait,5
Benjamin P. Howden,3,6,9 and Martyn D. Kirk1
Abstract
In Australia, the incidence of Salmonella Typhimurium has increased dramatically over the past decade. Whole-genomesequencing (WGS) is transforming public health microbiology, but poses challenges for surveillance. To compare WGS-based approaches with conventional typing for Salmonella surveillance, we performed concurrent WGS and multilocusvariable-number tandem-repeat analysis (MLVA) of Salmonella Typhimurium isolates from the Australian CapitalTerritory (ACT) for a period of 5 months. We exchanged data via a central shared virtual machine and performedcomparative genomic analyses. Epidemiological evidence was integrated with WGS-derived data to identify relatedisolates and sources of infection, and we compared WGS data for surveillance with findings from MLVA typing. Wefound that WGS data combined with epidemiological data linked an additional 9% of isolates to at least one other isolate inthestudy incontrast toMLVAandepidemiologicaldata, and 19%more isolates thanepidemiologicaldataalone.Analysisof risk factors showed that in one WGS-defined cluster, human cases had higher odds of purchasing a single egg brand.While WGS was more sensitive and specific than conventional typing methods, we identified barriers to uptake ofgenomic surveillance around complexity of reporting of WGS results, timeliness, acceptability, and stability. In con-clusion, WGS offers higher resolution of Salmonella Typhimurium laboratory surveillance than existing methods and canprovide further evidence on sources of infection in case and outbreak investigations for public health action. However,there are several challenges that need to be addressed for effective implementation of genomic surveillance in Australia.
Keywords: Salmonella Typhimurium, whole-genome sequencing, MLVA, public health, surveillance
Introduction
Nontyphoidal Salmonella (NTS) enterica causessignificant morbidity and mortality in Australia (Kirk
et al., 2014). Rates of NTS, particularly Salmonella Typhi-
murium, have been increasing and are higher in Australia thanother developed nations, including the United States and theEuropean Union (Ford et al., 2016). While NTS is transmittedthrough several routes, approximately three-quarters of salmo-nellosis cases are estimated to be transmitted via contaminated
1National Centre for Epidemiology and Population Health, Research School of Population Health, The Australian National University,Canberra, Australia.
2OzFoodNet, Health Protection Service, Population Health Protection and Prevention, ACT Health, Canberra, Australia.3Doherty Applied Microbial Genomics, Department of Microbiology and Immunology, The University of Melbourne at The Peter
Doherty Institute for Infection and Immunity, Melbourne, Australia.4Centre for Infectious Diseases and Microbiology Laboratory Services, Pathology West—Institute of Clinical Pathology and Medical
Research, Sydney, Australia.5Centre for Infectious Diseases and Microbiology—Public Health, Marie Bashir Institute for Infectious Diseases and Biosecurity,
The University of Sydney, Sydney, Australia.6Microbiological Diagnostic Unit Public Health Laboratory, Department of Microbiology and Immunology, The University of Melbourne
at The Peter Doherty Institute for Infection and Immunity, Melbourne, Australia.7Sydney Medical School—Westmead, The University of Sydney, Sydney, Australia.8Instituto de Salud Publica, Facultad de Medicina, Universidad Austral de Chile, Valdivia, Chile.9Infectious Diseases Department, Austin Health, Heidelberg, Australia.
FOODBORNE PATHOGENS AND DISEASEVolume 15, Number 3, 2018ª Mary Ann Liebert, Inc.DOI: 10.1089/fpd.2017.2352
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food (Vally et al., 2014). Most foodborne NTS outbreaks inAustralia are due to Salmonella Typhimurium and have beenassociated with a variety of sources, although eggs and poultryare the most common (OzFoodNet Working Group, 2015). Inparticular, the number of Salmonella Typhimurium outbreaksassociated with eggs in Australia has increased from 2001 to2011 (Moffatt et al., 2016a).
Whole-genome sequencing (WGS) using high-throughputnext-generation sequencing offers an alternative to tradi-tional subtyping methods for NTS and other foodbornepathogens (Deng et al., 2016). WGS has been shown to bemore discriminatory and sometimes less expensive than tra-ditional typing methods (Deng et al., 2016). Internationally,there have been several examples of the application of WGSto investigate outbreaks and for routine surveillance typing ofNTS (Byrne et al., 2014; den Bakker et al., 2014; Leekitch-aroenphon et al., 2014; Angelo et al., 2015; Ashton et al.,2015, 2016; Inns et al., 2017). However, there is limitedevidence on the effective and actionable use of WGS datawithin a public health unit. To examine the potential benefitsof WGS within a public health unit, we conducted a pro-spective trial of sequencing all Salmonella Typhimuriumisolates in the Australian Capital Territory (ACT) over aperiod of 5 months. We evaluated WGS performance forroutine public health surveillance using previously publishedguidelines as described by German et al. (2001).
Methods
Study design
In line with routine surveillance procedures, isolates cul-tured from human fecal, urine, or blood samples of ACTresidents were notified by the diagnostic laboratory to thepublic health unit and forwarded to either the Micro-biological Diagnostic Unit Public Health Laboratory (MDUPHL) in Melbourne or the Institute for Clinical Pathology andMedical Research (ICPMR)—Pathology West in Sydney forserotyping, and multilocus variable-number tandem-repeatanalysis (MLVA) if Salmonella Typhimurium. All isolatescollected between January 1, 2016, and June 2, 2016, ser-otyped as Salmonella Typhimurium, were included in thisstudy and were sequenced on a fortnightly basis either atMDU PHL or at ICPMR. The WGS inclusion criteria wereexpanded to include human isolates from two outbreaks inQueensland and food/environmental isolates from one out-break in New South Wales where epidemiological trace-backindicated a common source to outbreaks in the ACT.
Ethics approval for this project was granted by the ACTHealth Human Research Ethics Committee (16.215) and theAustralian National University Human Research EthicsCommittee (2016/528).
Phenotypic serotyping
The antigenic formulae of Salmonella isolates were de-termined using antisera that agglutinated with specific O(somatic) and H (flagellar) antigens and were classified intoserovars in accordance with the White–Kauffmann–LeMinor scheme (Issenhuth-Jeanjean et al., 2014). Isolatesserotyped as Salmonella Typhimurium were submitted forMLVA and WGS.
Multilocus variable-number tandem-repeat analysis
MDU PHL and ICPMR performed MLVA on all Salmo-nella Typhimurium isolates as previously described (Lind-stedt et al., 2004).
Whole-genome sequencing
Study isolates at either MDU PHL or ICPMR were sub-cultured for purity on nutrient agar twice before genomicDNA extractions from single colonies were performed usinga JANUS automated workstation (PerkinElmer) and an au-tomated DNA extraction instrument, Chemagic Prepito-D�
(PerkinElmer) based on magnetic particle separation enablingisolation of high-quality DNA. Extracted genomic DNA wasdiluted and DNA libraries prepared using the Illumina NexteraXT kit according to the manufacturer’s instructions (Illumina,Inc.). Following DNA Library preparation, quality control wasperformed using a PerkinElmer LabChip GX Touch bioana-lyzer and Thermo Fisher Qubit fluorometer to accuratelyquantitate the amount of DNA in each indexed library and todetermine the average size and DNA fragment distributionwithin each library. After normalization, indexed librarieswere mixed in the calculated ratios and WGS performed usingthe Illumina NextSeq 500 platform with 2 · 150 bp paired-endchemistry.
Data sharing and bioinformatic analysis
MDU PHL and ICPMR exchanged data via a dedicatedshared virtual machine running on the Australian NationalResearch Cloud (National eResearch Collaboration Toolsand Resources project or NECTAR). Each participatinglaboratory was provided with an account on the remotecomputer with a Secure Shell login. This allowed us to uploadsequencing data files over an encrypted channel, as well asbrowse and download the files uploaded by others. Noidentifiable patient data were uploaded to the cloud. Fol-lowing the study, the data were deleted, the virtual machinewas shut down, and its resources returned to the NECTARcloud.
We used the ‘‘Nullarbor’’ pipeline (https://github.com/tseemann/nullarbor) to de novo assemble and align short readdata against the Salmonella Typhimurium LT2 reference ge-nome (GenBank accession Nos. AE006468 and AE006471).Similarity between isolates was assessed by the identificationand alignment of core genome single-nucleotide polymor-phisms (SNPs). The core genome comprised 4248 genesthat are present in all isolates following comparison of thegenomes. Maximum likelihood phylogenetic trees were esti-mated with FastTree software using the general time revers-ibility model, and SNP distances were calculated with Snippyv3.1 (http://github.com/tseemann/snippy).
Public health follow-up
Where possible, we interviewed all notified cases of NTSusing a standardized questionnaire to obtain informationabout potential food and environmental exposures in the 7 dbefore illness onset under The Public Health Act 1997 inACT. If the case was identified as part of an outbreak, weused additional questions specific to the outbreak, or onlyinterviewed with an outbreak-specific questionnaire.
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Definitions
For the purposes of this study, a case was defined as anindividual with Salmonella Typhimurium notified to thepublic health unit, with a specimen collection date betweenJanuary 1 and June 2, 2016. Epidemiological evidence of alink was defined as in the 7 d before illness onset: havinghousehold contact with a known case; reporting eating at thesame commercial food premises as another case; buying thesame egg brand; swimming in the same pool or lake as an-other case; or reporting a similar environmental contact asanother case (e.g., handled the same pet food, attended thesame petting zoo). Isolation of Salmonella Typhimuriumfrom food or the environment in a food premises linked to aknown outbreak was considered an epidemiological link fornonhuman samples. Cases who reported travel outside ofAustralia or within Australia but outside the ACT in the 7 dbefore illness onset were classified as travelling overseas orinterstate, respectively.
Isolates were defined as linked by MLVA if they had anidentical MLVA profile, and linked by WGS if they were £8SNPs from any other isolate in the cluster. This SNP cutoffwas chosen from observed SNPs in known outbreaks in thesedata. This cutoff will need to be further evaluated for futureanalyses.
An outbreak was defined as two or more cases who con-sumed a common food, or food from a common commercialfood premises, and epidemiological and/or microbiologicalevidence implicated the food or premises as the source ofillness. A cluster was defined as fully supported if all cases inthe cluster were linked by epidemiological evidence, anddefined as partially supported if two or more, but not all casesin the cluster, were linked by epidemiological evidence.
Analysis
We conducted descriptive analysis on deidentified data ofall NTS cases in the ACT during the study period to deter-mine the proportion of NTS isolates cultured and forwardedto a reference laboratory, as well as the number of isolatessequenced and the number in an epidemiological, MLVA, orWGS-defined cluster.
We used a case/case analysis for one WGS-identifiedcluster, where cases were isolates in the cluster, and controlswere randomly selected from both Salmonella Typhimuriumcases outside the cluster and non-Typhimurium NTS casesduring the study period. Questionnaire data were combinedwith cluster variables for MLVA and WGS and analyzedusing Microsoft Excel 2013 and Stata SE 14. Univariableanalysis with a Fisher’s exact test was used to generate anodds ratio and p-value.
Evaluation of WGS for surveillance
We qualitatively evaluated the implementation of WGS asa surveillance system based on its performance, particularlythe sensitivity and specificity, positive predictive value,simplicity, timeliness, acceptability, and stability (Germanet al., 2001).
Results
Of the 108 Salmonella Typhimurium isolates sequenced,there were 92 human isolates from 90 ACT residents, 13
human isolates from Queensland residents, 2 food isolates,and 1 environmental isolate from a food premises. Overall,MDU PHL sequenced 80% (86/108) and ICPMR sequenced20% (22/108) of the Salmonella Typhimurium isolates.Where two people provided two stool specimens on differentdates (10 and 1 d apart, respectively), there were no SNPdifferences found between sequential isolates.
WGS data identified 14 clusters of 2 or more isolates with£8 SNPs (median cluster size 3, range 2–32 isolates), whileMLVA data only identified 11 clusters with the same MLVAprofile (median cluster size 5, range 2–31 isolates). Epide-miological evidence fully supported 43% (6/14) and partiallysupported a further 43% (6/14) of the WGS clusters, com-pared to fully supporting 18% (2/11) and partially supportinga further 73% (8/11) of the MLVA clusters (Table 1).Overall, WGS with epidemiological data linked 9% (10/108)more isolates to at least one other isolate in the study thanMLVA and epidemiological data, and 19% (21/108) moreisolates than epidemiological data alone.
Of isolates linked by WGS, 24% (21/86) did not report anillness onset within 2 weeks of another isolate in the cluster oroutbreak occurrence. While some of the WGS clusters re-presented already recognized outbreaks (Ford et al., 2017)(Supplementary Data and Supplementary Figure 1; Supple-mentary Data are available online at www.liebertpub.com/fpd),exposure data in some of these WGS clusters were not directlycompared before receiving the WGS data due to differences inMLVA profiles or time of illness onsets. Epidemiological dataoverlaid with WGS data showed that cases in WGS clusters, whohad not previously been linked by epidemiological data, oftenreported buying the same egg brand (Fig. 1). A case/case anal-ysis of one of these clusters showed that cases within the WGScluster had a higher odds of reporting egg brand D comparedwith cases outside the cluster (odds ratio 45, 95% confidenceinterval 1.34–2507.21, p = 0.01).
Evaluation
Sensitivity and specificity
While culture-independent diagnostic testing has in-creased recently (Iwamoto et al., 2015), pathology providersin the ACT still culture most stool specimens from patientswith diarrhea for NTS (R Hundy, personal communication,
Table 1. Number and Percent of Salmonella
Typhimurium Isolates Linked to at Least One
Other Isolate in the Study Through Epidemiological
Data, Multilocus Variable-Number Tandem-Repeat
Analysis, and Whole-Genome Sequencing Data,
Australian Capital Territory, January to June 2016
Linked by
Isolates (n = 108)
N %
Epidemiological data alone 48 44MLVA alone 89 82WGS alone 86 80MLVA and epidemiological data 59 55WGS and epidemiological data 69 64
MLVA, multilocus variable-number tandem-repeat analysis;WGS, whole-genome sequencing.
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2017). During the study period, 7% of NTS notifications werederived from nucleic acid testing only with no isolatesavailable, and 2% of notifications were cultured but isolateswere not forwarded to the reference laboratory for furthercharacterization.
WGS data were sensitive to detect outbreaks, identifyingmore genetically linked cases than epidemiological data andMLVA alone. WGS data were also specific by showing ge-netic differences within an MLVA profile and thus excludingsome cases from an MLVA-defined cluster.
Predictive value positive
All isolates (100%) linked by both epidemiological dataand MLVA were also linked by WGS, including cases indifferent states and territories. WGS data showed close ge-netic relatedness between sporadic cases (some occurringmonths after an outbreak) to point-source outbreaks or toother isolates of suspected sporadic infection.
Simplicity and timeliness
Reference laboratories perform and report NTS typingresults independently of each other; however, in this study,sequencing data needed to be shared for a combined analy-sis and report for effective surveillance of all SalmonellaTyphimurium in the ACT. A virtual machine was establishedto share data between two laboratories and bioinformaticexpertise was required for the analysis and report of WGSdata. Public health unit staff needed training in WGS datainterpretation. With current systems, the WGS analysis wasmore time-consuming than the analysis of MLVA profiles,even for a relatively small number of isolates.
As seen for Listeria monocytogenes in the United States( Jackson et al., 2016), due to the highly discriminatory powerof WGS, less data (fewer isolates) should be required toidentify an outbreak, facilitating timely intervention. In thisstudy, traditional typing methods were performed and theirresults reported before sequencing, and WGS data were notavailable early enough to be used to first identify an outbreak.
Acceptability and stability
The largest barriers to acceptability from the public healthunit were the capacity to understand and use the data, and thecost of sequencing. While the costs of WGS have been de-creasing and are likely to continue to decrease (Wang et al.,2015; Deng et al., 2016), at the time of this study, the cost ofWGS to the public health unit was higher than the combinedcost of serotyping and MLVA. Using WGS for surveillancerelies on the expertise and communication among microbi-ologists, bioinformaticians, and epidemiologists, and is notflexible to the loss of personnel who can sequence and in-terpret the data.
Discussion
Our findings demonstrated that even with a relatively smallnumber of culture-confirmed cases of Salmonella Typhi-murium gastroenteritis, WGS of Salmonella Typhimuriumwas more discriminatory than MLVA. WGS with epidemi-ological data was both sensitive (linking 9% of cases thattraditional typing had not linked) and specific (differentiatingisolates with the same MLVA profile that were not part of anoutbreak). WGS improved source attribution of SalmonellaTyphimurium cases by linking food and environmental iso-lates in an outbreak, and by identifying clusters with higherprecision for risk factor analysis—in this study, identifyingegg brands for further investigation. This high discriminationis invaluable at the public health unit level to better targetedepidemiological investigations.
Our results are consistent with reports from Denmark andthe United States, which identified benefits of WGS for Sal-monella Enteritidis compared to pulsed-field gel electropho-resis (den Bakker et al., 2014; Leekitcharoenphon et al.,2014).Several other recent studies have used WGS to help retro-spectively investigate NTS outbreaks in the United States,United Kingdom, and Europe (Byrne et al., 2014; Ashtonet al., 2015; Inns et al., 2015; Taylor et al., 2015; Hoffmannet al., 2016). Characterizing NTS by WGS is becoming morecommon, with Public Health England now routinely usingWGS for prospective characterization of all NTS (Ashtonet al., 2016). The improved sensitivity and specificity of WGScompared to phage typing likely increased the speed at which amulticountry outbreak of NTS in the United Kingdom andSpain in 2015 was recognized (Inns et al., 2017).
Several studies have suggested that WGS can also be usedto genetically link NTS isolates from food or environmentalsources to isolates from human cases, which can help torapidly identify the source of an outbreak (Yokoyama et al.,2014; Ashton et al., 2015; Inns et al., 2015). However, for thisto occur, NTS isolates from food and environmental sourcesneed to be sequenced, as, for example, has been done with theU.S. Food and Drug Administration’s GenomeTrakr (Allardet al., 2016). A database of NTS sequences from local sourcesmight have assisted this ACT project to identify sources ofinfection. Salmonella Typhimurium was only isolated fromfood or the environment in one outbreak, with the isolatesbeing highly related to those of the human cases from thatoutbreak. While risk factor information from cases providedsome evidence of food or environmental sources of infection,this evidence would be strengthened if isolates from thesesources could be linked through WGS.
We identified a number of implementation challenges ofWGS surveillance within the public health unit. While our useof SNP differences to assess relatedness between cases pro-vided high discrimination, they may be dependent on the se-lection of reference genomes, can change as the number ofisolates in the analysis increases, and require a national database
FIG. 1. Maximum likelihood core genome SNP phylogeny of Salmonella Typhimurium isolates with epidemiologicaldata, ACT, January to June 2016. Clusters identified by WGS are highlighted in the tree. Figure created with InteractiveTree of Life (https://itol.embl.de). Note: Where there was epidemiological or environmental evidence that an outbreak wasassociated with eggs, all cases in the outbreak were assigned that egg brand. Outbreak-associated case isolates were isolatesepidemiologically linked with a known outbreak. ACT, Australian Capital Territory; SNP, single-nucleotide polymorphism;WGS, whole-genome sequencing. Color images available online at www.liebertpub.com/fpd
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for data sharing and analysis. This highlighted the need for anew system to integrate WGS results into current systems, asWGS data and epidemiological data needed to be manuallyoverlaid for analysis. Unlike a Campylobacter outbreak in theACT, where there were large SNP distances between epide-miologically linked cases (Moffatt et al., 2016b), we did notfind any cases where epidemiological evidence linked them, butWGS data did not. However, WGS data suggested links be-tween cases where there was no supporting epidemiologicalevidence. It is unclear how much evidence is needed to triggerfurther investigation or how resource intensive that investigationshould be. Finally, routine WGS for Salmonella Typhimuriumsurveillance remains costly, and the current turn-around-time ofWGS exceeds that of traditional methods. Using WGS as asurveillance system is unstable without sustainable funding forthe costs of WGS. Investment into continued training and in-frastructure to share data nationally and combine epidemio-logical data with WGS data is needed. While WGS is highlydiscriminatory, if the data are not received in a timely manner,this limits the utility for public health surveillance. We wereunable to measure timeliness of WGS in this study as traditionaltyping methods were performed before sequencing began.
Our study had a relatively small number of isolates andsmall cluster sizes, which limited our power to detect sig-nificant associations between risk factors and illness withinclusters. Despite this, our study showed the potential of WGSto link ‘‘sporadic’’ cases, which could be increased if otherAustralian states and territories contributed data.
In conclusion, WGS of Salmonella Typhimurium presentsa more discriminatory approach to laboratory surveillancethan MLVA and has the potential to identify outbreaks andsources of infection investigated by a small public health unit.If sequenced and reported in a timely manner, this couldincrease the speed of preventative action and reduce thenumber of illnesses. Several challenges need to be addressedbefore WGS can be used routinely in a public health unit,including reporting, triggers for investigation, and sustain-able funding and resources. This study facilitated close col-laboration among epidemiologists, microbiologists, andbioinformaticians, a key requirement for an effective transi-tion to WGS for NTS.
Acknowledgments
The authors thank ACT Health and OzFoodNet. They alsothank the laboratories that performed the serotyping, MLVA,and WGS, including the MDU PHL, the ICPMR, andQueensland Health Forensic and Scientific Services (FSS).Doherty Applied Microbial Genomics is funded by the De-partment of Microbiology and Immunology at The University ofMelbourne. The National Health and Medical Research Coun-cil, Australia, funded a Practitioner Fellowship GNT1105905 toB.P.H. and Project Grant GNT1129770 to B.P.H., D.A.W, andM.D.K. Finally, they thank Milica Stefanovic, Russel Stafford,Kirsty Hope, Craig Shadbolt, and John Bates for their con-tribution to this project. This research is supported by anAustralian Government Research Training Program (RTP)Scholarship.
Disclosure Statement
No competing financial interests exist.
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Seven Salmonella Typhimurium Outbreaks in AustraliaLinked by Trace-Back and Whole Genome Sequencing
Laura Ford,1,2 Qinning Wang,3 Russell Stafford,4 Kelly-Anne Ressler,5 Sophie Norton,6 Craig Shadbolt,7
Kirsty Hope,8 Neil Franklin,8 Radomir Krsteski,2 Adrienne Carswell,2 Glen P. Carter,9 Torsten Seemann,9
Peter Howard,3 Mary Valcanis,10 Cristina Fabiola Sotomayor Castillo,3,11–13 John Bates,14 Kathryn Glass,1
Deborah A. Williamson,9,10 Vitali Sintchenko,3,13 Benjamin P. Howden,9,10,15 and Martyn D. Kirk1
Abstract
Salmonella Typhimurium is a common cause of foodborne illness in Australia. We report on seven outbreaksof Salmonella Typhimurium multilocus variable-number tandem-repeat analysis (MLVA) 03-26-13-08-523(European convention 2-24-12-7-0212) in three Australian states and territories investigated between November2015 and March 2016. We identified a common egg grading facility in five of the outbreaks. While noSalmonella Typhimurium was detected at the grading facility and eggs could not be traced back to a particularfarm, whole genome sequencing (WGS) of isolates from cases from all seven outbreaks indicated a commonsource. WGS was able to provide higher discriminatory power than MLVA and will likely link more SalmonellaTyphimurium cases between states and territories in the future. National harmonization of Salmonella surveillanceis important for effective implementation of WGS for Salmonella outbreak investigations.
Keywords: Salmonella Typhimurium, whole genome sequencing, outbreaks, trace-back, eggs
Introduction
The incidence of nontyphoidal Salmonella entericahas been increasing in Australia (Ford et al., 2016).
Unlike in the United States and Europe, Salmonella sero-type Typhimurium is the most common cause of humanSalmonella infection and outbreaks in Australia (Fordet al., 2016). Salmonella serotype Enteritidis is not en-demic in Australian egg-laying flocks and makes up only
about 6% of nontyphoidal S. enterica notifications of humaninfection nationally (OzFoodNet Working Group, 2015; Fordet al., 2016).
Although Salmonella Typhimurium is believed to be en-demic in layer flocks in Australia, there is no ongoing, sys-tematic national surveillance of Salmonella in poultry farms(Chousalkar et al., 2016). Commercial egg farms and gradingfacilities are subject to a number of regulatory controls, in-cluding audits and inspections, which aim to ensure adequate
1National Centre for Epidemiology and Population Health, Research School of Population Health, The Australian National University,Canberra, Australia.
2OzFoodNet, Health Protection Service, Population Health Protection and Prevention, ACT Health, Canberra, Australia.3Centre for Infectious Diseases and Microbiology Laboratory Services, Pathology West—Institute of Clinical Pathology and Medical
Research, Sydney, Australia.4Communicable Diseases Branch, Prevention Division, Queensland Health, Brisbane, Australia.5South Eastern Sydney Local Health District, NSW Health, Sydney, Australia.6Western Sydney Local Health District, NSW Health, Penrith, Australia.7New South Wales Food Authority, Sydney, Australia.8New South Wales Ministry of Health, Sydney, Australia.9Doherty Applied Microbial Genomics, Department of Microbiology and Immunology, The University of Melbourne at The Peter
Doherty Institute for Infection and Immunity, Melbourne, Australia.10Microbiological Diagnostic Unit Public Health Laboratory, Department of Microbiology and Immunology, The University of Melbourne
at The Peter Doherty Institute for Infection and Immunity, Melbourne, Australia.11Sydney Medical School—Westmead, The University of Sydney, Sydney, Australia.12Instituto de Salud Publica, Facultad de Medicina, Universidad Austral de Chile, Valdivia, Chile.13Centre for Infectious Diseases and Microbiology—Public Health, Marie Bashir Institute for Infectious Diseases and Biosecurity, The
University of Sydney, Sydney, Australia.14Public Health Microbiology, Public & Environmental Health, Forensic and Scientific Services, Health Support Queensland, Department
of Health, Coopers Plains, Australia.15Infectious Diseases Department, Austin Health, Heidelberg, Australia.
FOODBORNE PATHOGENS AND DISEASEVolume 15, Number 5, 2018ª Mary Ann Liebert, Inc.DOI: 10.1089/fpd.2017.2353
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biosecurity and food safety accountability in egg productionto minimize Salmonella prevalence (Food Standards Aus-tralia New Zealand, 2012; Chousalkar et al., 2017). Addi-tional standards at retail level provide through chain foodsafety control of egg-based foods. Despite these controls,outbreaks associated with eggs and raw egg products haveincreased across Australia, and *37% of sporadic Salmo-nella cases and 59% of Salmonella outbreak cases have beenattributed to eggs (Glass et al., 2016; Moffatt et al., 2016;OzFoodNet Working Group, 2016a).
As Salmonella Typhimurium is the most common serotypein Australia, reference laboratories routinely perform multi-locus variable-number tandem-repeat analysis (MLVA) forSalmonella Typhimurium isolates to help detect and inves-tigate outbreaks. MLVA has been particularly useful in trace-back investigations of Salmonella Typhimurium outbreaksassociated with eggs (Chousalkar et al., 2017).
Whole genome sequencing (WGS) has also shown to en-able dramatic improvements in linking Salmonella cases re-lated to outbreaks, as well as attributing potential food orenvironmental sources and tracing back to production. WGShas recently been applied to several nontyphoidal S. entericaoutbreak investigations internationally (Angelo et al., 2015;Ashton et al., 2015; Inns et al., 2015, 2017). While not yetroutinely performed on all nontyphoidal S. enterica isolatesin Australia, WGS has been used in outbreaks and researchstudies.
Between November 2015 and March 2016, seven localizedoutbreaks of Salmonella Typhimurium MLVA type 03-26-13-08-523 (European convention 2-24-12-7-0212) wereidentified and investigated by Australian state and territoryagencies: three in New South Wales, two in the AustralianCapital Territory, and two in Queensland. Before these out-breaks, this MLVA profile was uncommon and had only oncebeen associated with a notified outbreak in Australia (Oz-FoodNet Working Group, 2016b). Investigations into theseseven outbreaks were initiated to identify the source of in-fection and implement control measures to prevent furthercases. In this report, we describe the epidemiological andenvironmental investigations of these outbreaks and examinerelatedness using WGS results, with the aim to provide fur-ther evidence of egg-associated salmonellosis in Australia.
Materials and Methods
Epidemiological investigations
Each outbreak was investigated by local public health of-ficials. We defined an outbreak as two or more cases ofSalmonella Typhimurium 03-26-13-08-523 who consumeda common food, or food from a common place. Outbreak-associated human cases were first identified locally fromthree sources: (1) following presentations of patients withgastroenteritis at a local emergency department, (2) fromnotifications of Salmonella infection either through routinecase interviews or MLVA profiles, or (3) through the sub-mission of a food complaint to food regulators.
Separate case definitions were generated for each of theoutbreaks (Supplementary Table S1; Supplementary Data areavailable online at www.liebertpub.com/fpd), but broadly in-cluded anyone who ate at the implicated food premises duringthe outbreak day or period and subsequently developed gas-trointestinal illness. Cases were interviewed with a similar
telephone-administered structured hypothesis generatingquestionnaire for Salmonella or local outbreak-specific ques-tionnaires to obtain information about potential exposures,including food eaten in the week before onset. We conductedcase series of affected persons in six outbreaks, and a cohortstudy to investigate the first outbreak.
Data entry, tabulation, and analysis were completed inMicrosoft Excel. Tables were constructed to compare theattack rates of gastroenteritis for persons exposed and notexposed to each food item, followed by the calculation ofunivariate relative risks (RR) and 95% confidence intervals(CIs) for individual exposures to illness. The public healthunit where the outbreak occurred led the individual outbreakinvestigations.
Food and environmental investigations
Food safety authorities in the affected states and territoryinspected the implicated food premises. Where possible,food or environmental samples were collected for testing.The inspections and sampling at these premises aimed toidentify any food safety hazards and detect contamination infood or the environment of the premises. We also conductedegg trace-back at the implicated food premises to identify ifthey were using a common egg supplier. We inspected an egggrading facility and the newest layer flock shed on the layerfarm next to the grading facility, where we collected samplesof chicken feces, feed, egg, and environmental swabs.
Microbiological investigation
The food and environmental samples collected from theimplicated food premises in each outbreak were tested inthe state or territory in which the outbreak occurred. Swabsamples from the egg grading facility were tested using amodified Australian Standard 5013.10 (Standards Australia,2009). This method incorporates nonselective liquid resus-citation and then screening for the presence of Salmonellausing a commercial polymerase chain reaction kit. Liquidresuscitation broths positive for Salmonella are confirmedculturally using liquid selective enrichment and solid selec-tive media for the isolation of Salmonella. Typical colonieswere inoculated onto plate count agar and individual coloniesconfirmed by matrix-assisted laser desorption/ionization timeof flight mass spectrometry. Confirmed Salmonella isolatesfrom the grading facility were sent to the MicrobiologicalDiagnostic Unit Public Health Laboratory (MDU PHL) forserotyping.
A number of isolates associated with these outbreakswere sequenced as part of a study to prospectively WGSSalmonella Typhimurium in the Australian Capital Terri-tory (Ford et al., 2018). Serotyping and MLVA of the isolateswere completed at MDU PHL in Victoria, the Institute forClinical Pathology and Medical Research (ICPMR) in NewSouth Wales, or Queensland Health Forensic and ScientificServices. Briefly, the antigenic formulae of isolates weredetermined using antisera and serotyped in accordance withthe White-Kauffman-Le Minor scheme (Issenhuth-Jeanjeanet al., 2014), and MLVA was performed as previouslydescribed (Lindstedt et al., 2004).
Sequenced isolates were then subcultured for purity, DNAextracted using Presto Mini gDNA Bacteria kit (GeneAid),and DNA libraries prepared using the Illumina Nextera XT
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kit (Illumina, Inc.). WGS was performed using the IlluminaNextSeq 500 platform with 2 · 150 bp paired—end chemis-try. The ‘‘Nullarbor’’ pipeline (https://github.com/tseeman/nullarbor) was used to trim the reads, check the sequence dataquality, and perform core genome single-nucleotide poly-morphisms (SNPs) by aligning short-read data against theSalmonella Typhimurium LT2 reference genome. The sig-nificant thresholds for SNP calling were set for a minimumcoverage at 30. The phylogenetic analysis was performed onthe generated SNP alignment file to infer core SNP phylog-eny using the maximum likelihood method at 100 bootstrapsby MEGA 7 (Kumar et al., 2016). We describe these methodsin more detail elsewhere (Ford et al., 2018).
While this study aimed to prospectively WGS all Salmo-nella Typhimurium 03-26-13-08-523 isolates from the Aus-tralian Capital Territory, sequencing was not performed inreal time. Isolates from outbreaks in Queensland were se-quenced at MDU PHL and added into the analysis after theoutbreaks had been identified and investigated. Additionalisolates from outbreaks in New South Wales were sequencedjust for this study at ICPMR and added into the analysisretrospectively.
Results
Epidemiological investigations
Between October 2015 and March 2016, there were 272cases of Salmonella Typhimurium 03-26-13-08-523 notifiedin the Australian Capital Territory, New South Wales, andQueensland (Fig. 1). Of these, 115 (42%) cases were linked to1 of 7 point-source outbreaks, with outbreak size ranging from
2 to 81 cases. In a cohort study of the first outbreak, personseating mayonnaise containing raw egg were 3.6 times (RR 3.6,95% CI 1.04-12.3) more likely to have developed illness thanthose who did not report eating the mayonnaise. In case in-terviews, cases linked to 3 of the other outbreaks also reportedeating foods containing eggs at the implicated food premises.We did not identify a single suspected food source throughcase interviews in the remaining 3 outbreaks (Table 1).
Food and environmental investigations
In 3 outbreaks, environmental investigations identifiedcontributing factors at the premises associated with the out-breaks, including the use of raw egg foods, poor hygiene,poor food storage, and a lack of food safety knowledge. In theother three outbreaks, no food safety compliance issues wereidentified in the environmental findings. Food samples werecollected in five outbreaks and environmental samples inthree outbreaks (Table 1 and Supplementary Table S2).
Trace-back investigation. We identified the eggs used atfood premises in five of the seven outbreaks (Table 1). In allfive, eggs were produced by company X. We used egg stampsand purchase invoices to trace back the eggs used in the fiveoutbreaks to the same grading facility. During the inspectionof the grading facility, no food safety compliance issues wereidentified. The grading facility processes *1 million cage,barn, and free-range eggs per day, including about 120,000from a farm onsite and 800,000 eggs from 15 different farms.As egg packaging with farm establishment number was notavailable from any of the outbreaks, and eggs from more thanone farm were processed at the same facility on the egg stamp
FIG. 1. Epidemic curve of sporadic and outbreak Salmonella Typhimurium 03-26-13-08-523 case notifications by weekin the Australian Capital Territory, New South Wales, and Queensland, Australia, October 2015 to June 2016. If illnessonset date was unknown, specimen collection date was used.
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date, trace-back to the individual farm level from egg stampsand invoices was not possible (Fig. 2).
Microbiological investigation
Salmonella was only detected from food (ready-to eatsalad items) and environmental samples collected from foodpremises in one outbreak (Table 1). Cross-contaminationwas suspected to be a contributing cause; so the 23 positivefood and environmental samples detected in this outbreakwere unable to indicate any one food as the source of con-tamination. A more detailed summary of each outbreak canbe found in the Supplementary Data and SupplementaryTables 1 and 2.
Environmental swabs were taken from a new layer shed onone of the farms supplying eggs to the grading facility andfrom the grading facility itself, from chicken cloacae, anesting rail, three egg conveyor belts, the preprocessed eggs,an egg pulp collection tub (prewash), and an egg pulp col-lection tub (postwash). Salmonella was cultured from theswab of the egg pulp collection tub (prewash). Of the threeisolates serotyped, two were Salmonella subsp. I 16:I,v:- andone was Salmonella Singapore.
In total, 37 isolates of the outbreak MLVA profile werewhole genome sequenced: 9 human isolates from the 2 out-breaks in the Australian Capital Territory, 13 human isolatesfrom the 2 outbreaks in Queensland, 12 human isolates fromthe 3 outbreaks in New South Wales, and 2 food isolates(cucumber and onion) and 1 environmental swab isolate(mixing bowl) from 1 of the outbreaks in New South Wales.The isolates were clustered together and highly related, with0–10 SNPs difference between all isolates tested (Fig. 3).
Discussion
WGS illustrates that human, food, and environmentalisolates from seven outbreaks of Salmonella Typhimurium03-26-13-08-523 across three Australian states and territoriesinvestigated between November and March 2016 were highlyrelated. While MLVA and epidemiological investigationsfirst identified the seven outbreaks and initiated investiga-tions, WGS was able to provide significantly more discrim-inatory detail to show that outbreaks across jurisdictions wererelated. While systemic retail level failures were importantcontributing factors in several of the outbreaks and we werenot able to definitively link the outbreaks through sampling,the WGS data and the food trace-back investigations suggestthat the outbreaks were linked to a common source, likely tobe eggs graded at the same facility. Salmonella Typhimurium03-26-13-08-523 was not isolated from any samples at theegg grading facility; however, the facility was only sampledon one occasion.
These seven Australian outbreaks demonstrate how WGScan help to definitively link cases over wide geographic areas.This suggests that these outbreaks, and many SalmonellaTyphimurium outbreaks occurring across Australia, (Oz-FoodNet Working Group, 2015) may not be isolated events,but associated with a common source. By linking more cases,WGS will help identify and prioritize these clusters for fur-ther investigation. If WGS is timely and cases can be linkedtogether soon after their onset of illness, an outbreak can bedetected and preventive measures taken sooner, ideally re-ducing the number of cases potentially affected. A limitation
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of this Australian investigation is that WGS results were notavailable in real time and were not used in immediate publichealth action. As Australia moves toward surveillance ofnontyphoidal S. enterica using WGS, it will be importantthat Salmonella surveillance is harmonized nationally to ef-fectively detect multistate outbreaks and take rapid publichealth action.
In this study, at the retail food service level, interventionswere implemented in three outbreaks to address noncompli-ances with food safety standards (such as inadequate foodhandling practice) and to prevent further cases. Interventionssuch as these that target food handlers and the public to raiseawareness about safe handling of eggs and raw egg products
have helped to control Salmonella Typhimurium outbreaks(Stephens et al., 2007; Craig et al., 2013). At the productionlevel, no interventions occurred due to these outbreaks. Eggsused by the individual food premises in this study couldnot be traced back to a specific farm without egg cartons orpackaging. No specific reasons contributing to a higher prev-alence of Salmonella on eggs were identified and SalmonellaTyphimurium was not isolated at the grading facility.
Trace-back is often difficult, with a low prevalenceof Salmonella, particularly Salmonella Typhimurium, oncommercially produced eggs in Australia, and a failure torecover the outbreak strain on farms in 49% of SalmonellaTyphimurium outbreaks where testing occurred between
FIG. 2. Flowchart describing egg trace-back process with a large commercial egg producer.
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2000 and 2011 (Daughtry et al., 2005; Chousalkar andRoberts, 2012; Moffatt et al., 2016). In addition, the eggdistribution network is complex. Reducing the burden ofegg-associated salmonellosis cases in Australia requirescontinued collaboration and communication between pub-lic health officers, food regulators, and industry groups tostrengthen control measures at the point of production, atretail and wholesale, and at the consumer level (Craig et al.,2013; Moffatt et al., 2016).
To prevent egg-associated outbreaks such as the onesdiscussed in this study, additional Salmonella control mea-sures across the supply chain, particularly at retail and onfarm, have been implemented over the last few years. Somefood safety regulators have implemented stronger require-ments around the production and service of raw egg foods,including minimum levels for pH and maximum length ofstorage. This has been complemented by additional mandatorytraining for retail food service in cleaning and sanitizing pro-cedures, use of raw egg foods, and general skills and knowledge.The Australian egg industry has increased the level of awarenessof human salmonellosis as a significant issue. Strengthenedindustry education and food safety plans have been im-plemented, along with many laying flocks now vaccinated forSalmonella Typhimurium (Groves et al., 2016). Continuedcontrol measures are important for further prevention.
A limitation of this Australian outbreak investigation isthat WGS was not performed on all human isolates duringthe time period with the outbreak MLVA and we could notexclude any outlier cases from the outbreaks. In addition,the impact of WGS data from food or environmental isolateson control measures at retail or production could not beevaluated, as it was not timely and no isolates from the egggrading facility were sequenced because none were typed asSalmonella Typhimurium.
In the United Kingdom, where isolates of Salmonellaare routinely sequenced, WGS has been used successfullyto investigate Salmonella outbreaks associated with eggs.Similar to the investigation described in this study, cases ofSalmonella Enteritidis PT14b across the United Kingdomand Europe were found to be related through WGS andtraced back to imported eggs from a German egg producer in2014 (Inns et al., 2015). In addition, WGS of human andfood isolates was used to retrospectively investigate anoutbreak of Salmonella Typhimurium DT8 in the UnitedKingdom associated with a raw egg mayonnaise (Ashtonet al., 2015). More recently, prospective WGS was used tohelp detect a Salmonella Enteritidis outbreak associatedwith eggs, including cases from the United Kingdom andSpain (Inns et al., 2017). In these examples and in the out-breaks described in this study, WGS has been a useful tool
FIG. 3. Maximum likelihood core genome SNP phylogeny of Salmonella Typhimurium 03-26-13-08-523 isolates fromoutbreaks in the ACT, QLD, and NSW, 2015–2016. Figure created with Interactive Tree of Life (iTOL) (https://itol.embl.de). ACT, Australian Capital Territory; SNP, single-nucleotide polymorphism.
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by providing improved discrimination, enhancing outbreakinvestigations occurring across states or countries, or as-sisting with trace-back and control measures.
While we were unable to link cases to eggs produced bycompany X through food and environmental testing at thegrading facility, epidemiological evidence, egg trace-back,and WGS data indicate a likely common source for the casesin multiple-point source outbreaks occurring over severalmonths in three Australian states and territories. The increasein egg-associated outbreaks and egg-associated salmonello-sis since 2000 remains a concern in Australia (Moffatt et al.,2016). WGS is a tool that will provide more evidence toimplement preventative measures at retail and at production,and will be most effective if WGS data are timely, nationallyharmonized, and integrated with food and environmentalisolates.
Acknowledgments
The authors would like to thank ACT Health, NSW Health,Queensland Health, and OzFoodNet. We would also liketo thank the laboratories that performed the serotyping,MLVA, and WGS, including the ICPMR, the MDU PHL,and Queensland Health Forensic and Scientific Services. Doh-erty Applied Microbial Genomics is funded by the Departmentof Microbiology and Immunology at The University of Mel-bourne. The National Health and Medical Research Council,Australia, funded a Practitioner Fellowship GNT1105905 toB.P.H. and Project Grant GNT1129770 to B.P.H., D.A.W., andM.D.K. Finally, we would like to thank Milica Stefanovic andSam McEwen for their contribution to this project. This researchis supported by an Australian Government Research TrainingProgram (RTP) Scholarship.
Disclosure Statement
No competing financial interests exist.
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OzFoodNet Working Group. OzFoodNet quarterly report, 1April to 30 June 2014. Commun Dis Intell Q Rep 2016a;40:E290–E296.
OzFoodNet Working Group. OzFoodNet quarterly report, 1July to 30 September 2014. Commun Dis Intel Q Rep 2016b;40:E539–E544.
Standards Australia. 2009. AS 5013.10-2009. Microbiology offood and animal feeding stuffs—Horizontal method for thedetection of Salmonella spp. (ISO 6579:2002, MOD). Stan-dards Australia.
Stephens N, Sault C, Firestone SM, Lightfoot D, Bell C. Largeoutbreaks of Salmonella Typhimurium phage type 135 infectionsassociated with the consumption of products containing raw eggin Tasmania. Commun Dis Intell Q Rep 2007;31:118–124.
Address correspondence to:Laura Ford, MCHAM
National Centre for Epidemiology and Population HealthResearch School of Population Health
The Australian National UniversityCanberra, ACT 2601
Australia
E-mail: laura.ford@anu.edu.au
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Chapter 7. Impact of whole-genome sequencing on public
health surveillance two non-typhoidal Salmonella enterica
serotypes
7.1 Introduction
This chapter examines two case studies of how phylogenomic data from WGS can be used to
inform public health surveillance for zoonotic Salmonella infections. While most Salmonella
infections are transmitted through contaminated food, animals and contaminated
environmental sources are also important transmission pathways. In the rapidly developing
field of genomics, there is limited evidence on how to integrate epidemiological and genomic
data to better understand Salmonella serotypes for actionable public health prevention and
control strategies. This chapter aims to fill that gap, showing that phylogenomic data, combined
with epidemiological data, helps identify plausible sources of Salmonella infection from wildlife
and environmental reservoirs. The results provide a case for using phylogenomic analyses to
provide evidence for prevention and control strategies.
This chapter addresses the implications of whole genome sequencing for Salmonella
surveillance, prevention, and control. The paper has been published in Emerging Infectious
Diseases. Supplementary materials submitted with the paper can be found in Appendix 5.
7.2 Paper
Ford L, Ingle D, Glass K, Veitch M, Williamson DA, Harlock M, Gregory J, Stafford R, French
N, Bloomfield S, Grange Z, Conway ML, Kirk MD. A tale of two Salmonella serotypes in
Tasmania, Australia: how whole genome sequencing can inform prevention and control efforts.
Emerging Infectious Diseases. 2019;25(9):1690-1697, doi: 10.3201/eid2509.181811.
We used phylogenomic and risk factor data on isolates of Sal-monella enterica serovars Mississippi and Typhimurium de-finitive type 160 (DT160) collected from human, animal, and environmental sources to elucidate their epidemiology and disease reservoirs in Australia and New Zealand. Sequence data suggested wild birds as a likely reservoir for DT160; ani-mal and environmental sources varied more for Salmonella Mississippi than for Salmonella Typhimurium. Australia and New Zealand isolates sat in distinct clades for both serovars; the median single-nucleotide polymorphism distance for DT160 was 29 (range 8–66) and for Salmonella Mississippi, 619 (range 565–737). Phylogenomic data identified plausible sources of human infection from wildlife and environmental reservoirs and provided evidence supporting New Zealand–acquired DT160 in a group of travelers returning to Austra-lia. Wider use of real-time whole-genome sequencing in new locations and for other serovars may identify sources and routes of transmission, thereby aiding prevention and control.
Nontyphoidal Salmonella enterica subsp. enterica causes substantial illness and death throughout the
world (1,2). In Australia, rates of notified infection are
higher than in other high-income countries (3). Preventing infection by understanding sources and routes of transmis-sion and controlling outbreaks rapidly is key to reducing the rate of salmonellosis in Australia. Whole-genome se-quencing (WGS) is increasingly being used as a tool to help with prevention and control by investigating the relation-ship between isolates, sources of infection, and routes of transmission (4). Evidence shows that WGS is useful in foodborne nontyphoidal S. enterica outbreak detection and control (5–7).
On mainland Australia (Figure 1), Salmonella Ty-phimurium is the most commonly notified nontyphoidal S. enterica serovar. In contrast, Salmonella Mississippi is the most commonly notified nontyphoidal S. enterica se-rovar infecting residents of the island state of Tasmania, where 2.1% of the population of Australia resides (3,8). Most persons with Salmonella Mississippi who are resi-dents of mainland Australia have traveled to Tasmania or one of several Pacific Islands to which Salmonella Missis-sippi was endemic during their exposure period (9,10). In Tasmania, Salmonella Mississippi has been isolated from wildlife, and some evidence indicates that human infec-tions might result from environmental transmission more frequently than from foodborne transmission (9,11). A case–control study in Tasmania during 2001–2002 found that case-patients were more likely than controls to have had indirect contact with native birds, consumed untreated drinking water, and traveled within the state (9), although the sources of infection and vehicles of transmission are still largely unknown.
Salmonella Typhimurium definitive type 160 (DT160) has more recently emerged in Tasmania, while remaining rare in the rest of the country. In 2008, ten years after its emergence in humans in New Zealand, the first locally ac-quired case of DT160 was reported in Tasmania; unusual sparrow (Passer domesticus) deaths were observed in the same area in 2009, consistent with sparrow deaths in New
Whole-Genome Sequencing of Salmonella Mississippi and
Typhimurium Definitive Type 160, Australia and New Zealand
Laura Ford, Danielle Ingle, Kathryn Glass, Mark Veitch, Deborah A. Williamson, Michelle Harlock, Joy Gregory, Russell Stafford, Nigel French, Samuel Bloomfield,
Zoe Grange, Mary Lou Conway, Martyn D. Kirk
1690 Emerging Infectious Diseases • www.cdc.gov/eid • Vol. 25, No. 9, September 2019
Author affiliations: The Australian National University, Acton, Australian Capital Territory, Australia (L. Ford, D. Ingle, K. Glass, M.D. Kirk); The University of Melbourne at the Peter Doherty Institute for Infection and Immunity, Melbourne, Victoria, Australia (D. Ingle, D.A. Williamson); Department of Health, Hobart, Tasmania, Australia (M. Veitch, M. Harlock); Victorian Department of Health and Human Services, Melbourne (J. Gregory); Queensland Department of Health, Brisbane, Queensland, Australia (R. Stafford); New Zealand Food Safety Science and Research Centre, Manawatu-Wanganui, New Zealand (N. French); Massey University, Manawatu-Wanganui (N. French); Quadram Institute, Norwich, UK (S. Bloomfield); University of California– Davis, Davis, California, USA (Z. Grange); Department of Primary Industries, Parks, Water and Environment, Hobart (M.L. Conway)
DOI: https://doi.org/10.3201/eid2509.181811
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Zealand in 2000 (12–15). Since then, DT160 has affected ≈50 Tasmania residents and ≈3,000 New Zealand residents and has been associated with wild bird deaths in both coun-tries (16–18). Although a case–control study conducted in 2001 in New Zealand suggested that handling of dead wild birds, contact with persons with diarrheal illness, and ingestion of fast food were associated with illness (12), the relationship between the Tasmania and New Zealand DT160 infections and the relationship between animal and human isolates in Tasmania is unknown. Accordingly, we aimed to use these 2 nontyphoidal S. enterica serovars as case studies to investigate how epidemiologic and genomic data can be integrated to better understand the geographic niche and transmission pathways of these organisms to subsequently improve prevention and control strategies.
Methods
Ethics Considerations and Data SourcesThe Australian National University Human Research Eth-ics Committee (2016/269) granted ethics approval for this project. We used data from the Australian National Notifi-able Diseases Surveillance System (18) and the New Zea-land Enteric Reference Laboratory (19) to examine trends in Salmonella Mississippi and DT160 in Australia and New Zealand. Population denominator data were obtained from the Australian Bureau of Statistics (8) and Statistics New Zealand (20). We used postcode of residence to determine Australian state or territory. Travel information was not available, so postcode might not represent place of acquisi-tion for all notifications.
We collated epidemiologic data obtained through en-hanced surveillance of cases of Salmonella Mississippi and
DT160 that were notified to the Department of Health and Human Services in Tasmania, the Department of Health and Human Services in Victoria, and Queensland Health. Case-patients were interviewed at the time of notification using a standardized questionnaire, and this information was collected under each jurisdiction’s public health leg-islation. For human isolates for which sequence data were available, we obtained the following case data fields from these questionnaires: type of case (sporadic, household, cluster, outbreak); hospitalization (yes/no); symptoms; travel; close contact with farm animals, native animals, birds, or pets (yes/no and type); lives on a rural property (yes/no); bushwalking or camping (yes/no); water source (public, private, or bottled); gardening (yes/no); swimming (yes/no); other risk factors (free text). Data on risk factors were collected for the week before illness onset.
Isolate SelectionFor Salmonella Mississippi, we selected 34 human iso-lates from Tasmania residents and 28 human isolates from residents of other states and territories in Australia that were referred for characterization to the Microbio-logical Diagnostic Unit Public Health Laboratory (MDU PHL) in Melbourne during January 1, 2011–December 31, 2015, for WGS (Appendix, https://wwwnc.cdc.gov/EID/article/25/9/18-1811-App1.pdf). We also selected all viable isolates with a recorded source from 42 animal sources and 18 environmental sources in the MDU PHL collection with an isolation date from January 1, 2000, through December 31, 2016; these isolates were all from Tasmania. For DT160, all viable isolates held in the MDU PHL collection at the beginning of 2016 were included in genomic analysis.
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Figure 1. Relative locations of Australia, New Zealand, and Vanuatu.
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Sequencing and BioinformaticsMDU PHL performed DNA extraction and WGS for the Australia isolates. Sequence libraries were prepared us-ing NexteraXT and sequenced on the Illumina NextSeq500 platform (Illumina, https://www.illumina.com) with 150 bp paired-end reads. Reads are available from the National Cen-ter for Biotechnology Information Sequence Read Archive (PRJNA319593). Salmonella Typhimurium L2 (accession no. NC003197 [https://www.ncbi.nlm.nih.gov/nuccore/NC_003197.2]) was used as a reference for DT160, and because complete genomes were not publicly available, we used a local reference (AUSMDU00020775) for Salmonella Mississippi by assembling 1 of the isolates in this analysis (Appendix). We included 10 publicly available draft assem-blies from 2011 through 2013 from New Zealand and the United States (Appendix) in the Salmonella Mississippi anal-ysis (21,22) and 106 publicly available DT160 genomes from 1992 through 2012 from humans, wild birds, poultry, and bovine sources in New Zealand in the DT160 analysis (16).
Salmonella Mississippi and DT160 genomes were an-alyzed separately using Nullarbor version 2 (https://github.com/tseemann/nullarbor). Short-read data of the isolates were mapped to the reference using Snippy version 4.0-dev2 (https://github.com/tseemann/snippy). The 10 public-ly available Salmonella Mississippi draft assemblies were also mapped to the Salmonella Mississippi reference using Snippy , with the –ctgs parameter that enables mapping of assembly contigs to a reference. A core genome alignment was produced using Snippy-core (v4.0-dev 2), and the re-sulting full alignment was then filtered for recombination using Gubbins (23) using the weighted Robinson-Foulds method to estimate convergence with an initial 10 itera-tions. The resulting recombination-filtered core genome alignment of 8,573 bases for Salmonella Mississippi and 2,203 bases for DT160 was then passed to RAxML ver-sion 8.2.11 (24) to infer maximum-likelihood (ML) phylo-genetic trees, using the generalized time-reversible model with a γ-distribution to model site-specific rate variation and ascertain bias correction. For each analysis, we used
3 independent runs with 1,000 bootstrap pseudoreplicates to assess branch support, with the phylogenetic trees with the highest support across the 3 runs used as the final tree for each analysis. The pairwise single-nucleotide polymor-phism (SNP) distances between isolates were calculated from the recombination-filtered core genome alignment us-ing afa-pairwise.pl within Nullarbor. De novo genome as-semblies were generated using SPAdes version 3.12.0 (25), and the presence of known antimicrobial resistance genes was investigated using ABRicate (https://github.com/tsee-mann/abricate) in conjunction with the genome assemblies and the National Center for Biotechnology Information an-timicrobial resistance database with a minimum coverage of 90% and minimum identity of 90%.
Data AnalysisWe collated epidemiologic and SNP data in Microsoft Ex-cel 2013 (https://www.microsoft.com) and performed de-scriptive analyses in Stata SE 14 (https://www.stata.com). We used sequence data to explore hypotheses about the epidemiologic relatedness of isolates. We compared risk factors between DT160 and Salmonella Mississippi cases using a 2-sample test of proportions. Based on SNPs be-tween isolates of each serovar with known epidemiologic links (household or epidemiologic cluster), we considered isolates within 8 SNPs of each other for DT160 and 10 SNPs of each other for Salmonella Mississippi a putative phylogenetic cluster for further investigation.
Results
Salmonella MississippiDuring January 1, 2000–December 31, 2016, the me-dian annual notification rate of Salmonella Mississippi in Tasmania was 15 cases (range 12–24 cases) per 100,000 population, compared with a notification rate of 0.11 cases (range 0.007–0.16 cases) per 100,000 population on main-land Australia and 0.3 cases (range 0.16–0.47 cases) per 100,000 population in New Zealand (Figure 2). In Australia,
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Figure 2. Notification rates for Salmonella enterica serovar Mississippi, Tasmania (A) and mainland Australia and New Zealand (B), 2000–2016. Rates are per 100,000 population.
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934 (50.5%) of 1,851 notifications occurred in female pa-tients. Children 0–4 years of age were the most frequently notified age group (458 [24.7%]). Notification rates were higher in warmer months, similar to those for other non-Typhimurium serovars (26).
For sequenced Salmonella Mississippi isolates, the ML tree showed that the isolates from Vanuatu, United States, and New Zealand were distinctly different from the Austra-lia isolates (Figure 3); median SNP distance was 619 (range 565–737) between Australia and New Zealand isolates (Appendix Figure 1) and 1,625 (range 963–1,923) between Australia and Vanuatu or US isolates. An isolate from a 17-week-old mainland Australia resident with no history of overseas travel grouped on the phylogenetic tree with the isolates acquired in Vanuatu. Within the large Austra-lia group, the 114 isolates were diverse; median SNP dis-tance was 169 (range 3–649). Of these Australia isolates, 24 (21.1%) of 114 were within 10 SNPs of another isolate and grouped into 8 phylogenetic clusters. The Australia hu-man isolates grouped with Australia animal and environ-mental isolates over several years. We observed consider-able genetic diversity between isolates from various animal sources. For example, isolates from wombats were a me-dian of 87 (range 44–97) SNPs apart, and isolates from bo-vines were a median of 140 (range 10–201) SNPs apart. We did not detect any antimicrobial resistance genes in these
isolates, except for 1 human isolate from Tasmania that had the blaTEM-1 gene, which mediates resistance to ampicillin.
Travel data were available for 51 (82%) of 62 of case-patients in Australia residents for which an isolate was sequenced. Of these, 6 (12%) reported international travel to Vanuatu and 19 (37%) reported domestic travel during their incubation period; 8 traveled from mainland states to Tasmania, 9 traveled within Tasmania, 1 traveled from Queensland to South Australia, and 1 traveled from Victoria to Queensland. Three Tasmania isolates investi-gated as an epidemiologic cluster clustered genetically and temporally with an isolate from Victoria, for which no epi-demiologic data were available. Although 2 other phylo-genetic clusters included >1 human isolate, epidemiologic data were limited for these cases, and the infections were not clustered in time. Although not statistically significant, among case-patients who resided in or were known to have acquired infection in Tasmania and answered risk factor questions about exposures, a higher proportion of Salmo-nella Mississippi than DT160 case-patients reported drink-ing water from an untreated raw water source (i.e., tank, spring, or bore) (61% vs. 40%; p = 0.1) and camping (8% vs. 0%; p = 0.07) (Appendix Table 4). A similar propor-tion of DT160 and Salmonella Mississippi cases reported bushwalking (8% vs. 7.5%; p = 0.94), gardening (16% vs. 22%; p = 0.56), and swimming (16% vs. 18%; p = 0.84)
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Figure 3. Maximum-likelihood phylogeny of 132 sequenced Salmonella enterica serovar Mississippi isolates from Australia and New Zealand and reference isolates, inferred from 8,573 core single-nucleotide polymorphisms. Nodes are labeled with isolation year, isolate source if nonhuman (all from Tasmania), and Australia state of acquisition or residence if human. Tree visualized with iTOL (https://itol.embl.de) and midpoint rooted. Scale bar indicates nucleotide substitutions per site. *State of residence was used instead of state of acquisition because no travel data were available. †Investigated as part of an epidemiologic cluster. A color version of this figure is available online (http://wwwnc.cdc.gov/EID/article/25/9/18-1811-F3.htm).
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exposures. Of the 13 case-patients who resided in or ac-quired their infection in an Australia state other than Tas-mania, 4 (31%) reported eating oysters during the expo-sure period, including 2 cases in a phylogenetic cluster; however, not all case-patients were asked specifically about oysters.
Salmonella Typhimurium DT160A total of 61 DT160 cases in Australia residents were noti-fied during 1999–2014. The 12 infections reported in Aus-tralia residents before 2008 were believed to be acquired overseas, including cases on an Australia–New Zealand cruise in 2003. Most Australia DT160 notifications had a postcode of residence in Tasmania, where the median an-nual rate per 100,000 population of DT160 in the 9 years from 1999 to 2007 was 0 cases and in the 7 years from 2008 to 2014 was 1.2, peaking at 2.8 in 2009, when 14 cases occurred. In New Zealand, the median annual rate per 100,000 population of DT160 in the 9 years from 1999 to 2007 was 6, peaking at 20.4 in 2001, when 791 cases occurred. In the 7 years from 2008 to 2014, the median annual rate was 1.6 per 100,000 population (Figure 4). Of all 61 Australia notifications during 1999–2014, a total of 34 (56%) occurred in females, and children aged 0–4 years were the most frequently notified age group (14 [23%]). Because of the small number of cases, we found no clear seasonal pattern.
Of Australia isolates, we sequenced 62 human and 30 animal isolates (20 from sparrows). The ML tree of Austra-lia and New Zealand isolates showed 2 distinct groups; 1 comprised isolates from humans and animals in Australia, and 1 comprised humans and animals from New Zealand and the 7 Australia residents who had reported travel to New Zealand (Figure 5). The median pairwise SNP dif-ference between the Australia and New Zealand groups was 29 (range 8–66), and the median pairwise SNP dif-ference within each group was 21 (Australia, range 2–56; New Zealand, range 0–55) (Appendix Figure 4). Within the Australia group, 45 (53%) of 85 isolates were within
8 SNPs of another isolate, and the isolates grouped into 8 phylogenetic clusters. Of these 8 phylogenetic clusters, 3 contained >2 isolates; isolates from humans and birds over several years clustered. No known antimicrobial resistance genes were detected among any of the isolates.
Epidemiologic risk factor data were available for 55 (90%) of the 61 DT160 cases in Australia residents from the 62 sequenced human isolates (1 person contributed 2 isolates, 13 days and 7 SNPs apart). Of these 55 persons, 7 (12%) of 59 acquired their infection in New Zealand, 6 in 2003 on an Australia–New Zealand cruise, and 1 in 2009. All others were residents of, or had traveled to, Tasmania, except for 1 case-patient, who was a resident of New South Wales and had no reported travel outside the state. Two separate household clusters were investigated in 2012 and were phylogenetically clustered. In 2015, five isolates were investigated as part of an epidemiologic cluster; however, no epidemiologic link was found, and they were subse-quently found not to be phylogenetically clustered (median SNPs 25.5, range 9–33). A higher proportion of DT160 case-patients than Salmonella Mississippi case-patients re-ported direct contact with wild or domestic animals (88% vs. 68%; p = 0.04) (Appendix Table 4).
DiscussionPhylogenomics plays a valuable role in identifying plau-sible sources of Salmonella infection from wildlife and environmental reservoirs. For both serovars considered in this article, the integration of clinical and genomic data enhanced existing evidence on source reservoirs by show-ing that human and animal or environmental isolates were genetically interspersed. Phylogenomic analysis revealed genetic diversity and persistence of Salmonella Mississippi strains in the environment and animals, suggesting it is en-demic with a broad range of host reservoirs in Tasmania that is persisting over time. As in other countries (16,27–29), genomic analysis provided evidence that wild birds are a source of human infection with DT160. No character-ized antimicrobial resistance genes were detected in any of
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Figure 4. Salmonella enterica serovar Typhimurium definitive type 160 notification rate, Tasmania and mainland Australia (A) and New Zealand (B), 1999–2014. Rates are per 100,000 population.
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the DT160 draft genome sequences, suggesting low or no antimicrobial resistance, consistent with other Salmonella strains found in wild birds (30,31).
In contrast to Salmonella Mississippi, Salmonella Ty-phimurium DT160 isolates from Australia and New Zea-land were similar, suggesting possible recent trans-Tasma-nia transmission of DT160 through wildlife, as well as its potential to spread from Tasmania to the Australia main-land. Further, the inferred population structure of these Australia strains provided evidence for this hypothesis of import and subsequent microevolution within the Australia strains. In New Zealand, DT160 has been transmitted be-tween multiple hosts, and humans have been infected from multiple sources (16). Other Salmonella serovars with wild bird reservoirs have been transmitted to cattle, pigs, sheep, and poultry (32). The incidence of human infection in Aus-tralia most likely would increase if DT160 were to become established in local animal food sources.
Epidemiologic evidence that 88% of DT160 case-patients had direct animal contact and the close genetic relatedness between Australia human and animal isolates suggest that DT160 in Tasmania is predominantly a lo-cally acquired zoonotic infection. Control measures should therefore focus on promoting hand hygiene after contact with wild birds and other animals, keeping food prepa-ration and eating areas free from birds, treating drinking water that is accessible to birds and other animals, and
appropriately cleaning and maintaining birdfeeders (32,33). In addition to monitoring the effect of such measures, con-tinued isolation, identification, and WGS of DT160 isolates from humans, animals, and the environment could be used to monitor emergence in other settings that pose particular risks to the food supply and provide early warning of the need for specific control measures.
Risk factors for Salmonella Mississippi are less evident, although the proportion of case-patients who reported drink-ing water from a private source (61%) was similar to that of an Australia case–control study of Salmonella Mississippi (63% of case-patients vs. 23% of controls reported drinking any untreated water; adjusted odds ratio 6.13, 95% CI 3.19–11.76) (9). The range of animal and environmental sources and the high genetic diversity make identifying control strat-egies difficult. Because genomic analyses of WGS data have detected clusters when epidemiologic links are obscured (7), prospective WGS of case isolates and integration of WGS data from human, animal, and environmental isolates could help to identify putative clusters for targeted epidemiologic investigation. Source attribution studies might enable quan-tification of the contribution of raw water as a vehicle for Salmonella Mississippi infection in Tasmania.
One limitation of this study is that our sampling frame for sequencing and analysis might not have produced a representative sample of all infections; however, we tried to maximize variability of sources and isolation dates.
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Figure 5. Maximum-likelihood phylogeny of 198 sequenced Salmonella enterica serovar Typhimurium definitive type 160 isolates from Australia and New Zealand and reference isolates, inferred from 2,203 core single-nucleotide polymorphisms, Australia and New Zealand. Nodes are labeled with isolate type and isolation year. All Australian isolates are from Tasmania unless specified otherwise. Figure created with iTOL (https://itol.embl.de). Scale bar indicates nucleotide substitutions per site. *Specimens from the same person. †Investigated as part of an epidemiologic cluster. ‡Acquired in New South Wales. A color version of this figure is available online (http://wwwnc.cdc.gov/EID/article/25/9/18-1811-F5.htm).
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Although epidemiologic risk factor data were incomplete for sequenced human cases, sufficient data were available for us to generate hypotheses that could be further inves-tigated. Our case–case method is not as robust as a case–control study with a neutral control group, but we believe it is a reasonable point of comparison, emphasizing the difference in risk between these 2 serovars. Some more recent Australia DT160 notifications might not have been captured by the national notification system because phage typing for Salmonella Typhimurium is being phased out across Australia. However, we believe this omission would be a small number because phage typing continued in most of the country until 2016 (M. Valcanis, MDU PHL, pers. comm., 2018 Oct 10). Without phage typing, and as the use of WGS for Salmonella surveillance becomes more rou-tine, it will be difficult to compare new isolates with histori-cally phage-typed isolates that have not been sequenced.
We used SNP thresholds based on known epidemio-logic clusters to define putative phylogenetic clusters and to examine epidemiologic risk factors. Because SNPs de-pend on the reference genome and the isolates in the analy-sis, SNP thresholds for cluster analysis are likely to differ according to context. Local references were unavailable for both serovars in this study. We assembled a reference for Salmonella Mississippi using an isolate in this study, and the Salmonella Typhimurium isolate used was a median of 899 (range 883–921) SNPs from the DT160 isolates in our study. A closer reference for DT160 might have provided higher resolution of the relatedness of isolates. Few inter-national Salmonella Mississippi genomes were publicly available. Therefore, the relationship we found between Australia and New Zealand isolates might not be repre-sentative of all Salmonella Mississippi isolates in these 2 countries. Although beyond the scope of this study, iden-tifying the most recent common ancestor using Bayesian phylogeographic analyses would improve our understand-ing of endemic strains such as Salmonella Mississippi and the translocation of emerging strains such as DT160.
Wildlife can contribute to substantial rates of endemic and epidemic infection from Salmonella. For these 2 Sal-monella serovars with wild animal and environmental res-ervoirs in Australia and New Zealand, WGS combined with epidemiologic risk factor data provided some evidence for prevention and control efforts demonstrating the potential benefits of using WGS for prospective Salmonella surveil-lance. Real-time sequencing of these strains could help mon-itor emergence and identify clusters, enabling epidemiolo-gists to more accurately identify common risk factors and aid in source attribution. Local references, publicly available international genomes, phylogeographic analyses, additional tools to define a WGS cluster, and source-assigned case–control studies would improve our understanding of the epi-demiology of these 2 Salmonella serovars in this region.
AcknowledgmentsWe thank Kinley Wangdi for his assistance in generating the map in Figure 1. We also thank Anastasia Stylianopoulos, Marion Easton, Timothy Sloan-Gardner, and Robert Bell for their assistance in collecting case epidemiologic data. Finally, we thank John Bates, Mary Valcanis, Anders Gonçalves da Silva, Dieter Bulach, and Siobhan St. George for their assistance with sequence data and related metadata.
L.F. is supported by an Australian Government Research Training Program Scholarship. M.D.K. is supported by a National Health & Medical Research Council fellowship (APP1145997). D.A.W. is supported by a National Health & Medical Research Council fellowship (APP1123854).
About the AuthorMs. Ford is a PhD candidate in the Infectious Disease, Epidemiology, and Modelling group at the National Centre for Epidemiology and Population Health at the Australian National University. Her research interests include foodborne diseases and the application of sequencing for public health surveillance.
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13. Alley MR, Connolly JH, Fenwick SG, Mackereth GF, Leyland MJ, Rogers LE, et al. An epidemic of salmonellosis caused by Salmonella Typhimurium DT160 in wild birds and humans in New Zealand. N Z Vet J. 2002;50:170–6. https://doi.org/ 10.1080/00480169.2002.36306
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30. Hughes LA, Shopland S, Wigley P, Bradon H, Leatherbarrow AH, Williams NJ, et al. Characterisation of Salmonella enterica serotype Typhimurium isolates from wild birds in northern England from 2005–2006. BMC Vet Res. 2008;4:4. https://doi.org/10.1186/1746-6148-4-4
31. Afema JA, Sischo WM. Salmonella in wild birds utilizing protected and human impacted habitats, Uganda. EcoHealth. 2016; 13:558–69. https://doi.org/10.1007/s10393-016-1149-1
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Address for correspondence: Martyn D. Kirk, National Centre for Epidemiology and Population Health, Research School of Population Health, The Australian National University, Canberra, Australian Capital Territory, 2601 Australia; email: martyn.kirk@anu.edu.au
Emerging Infectious Diseases • www.cdc.gov/eid • Vol. 25, No. 9, September 2019 169783
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Chapter 8. Discussion and conclusion
In this thesis I have presented the results of seven studies investigating the epidemiology of
Salmonella in Australia and the impacts of WGS on public health surveillance and outbreak
investigation. Here, I synthesize the findings and implications and explore the future of whole
genome sequencing for Salmonella surveillance in Australia.
8.1 Findings and implications
The studies in my thesis offer findings and implications for one or more of my three research
themes below.
Trends and sources of infection
A main finding of my thesis is that Salmonella infections in Australia have been increasing
over time. I found that the incidence of Salmonella notifications to public health departments
in Australia increased to 53.0 cases per 100,000 population over 2000–2013. There were
national annual increases of 6% (95% confidence intervals 6%-7%) for Salmonella
Typhimurium and 3% (95% CI 2%-3%) for non-Typhimurium Salmonella. I also found that
there was an increase in the number of reported outbreaks of Salmonella in Australia over
2001–2016, peaking at 116 outbreaks reported in 2014. These findings, together with
comparatively high rates of Salmonella compared to other high-income countries (CDC, 2017;
EFSA and ECDC 2018; Government of Canada, 2019), indicate that prevention and control
measures over these time periods have not been successful in Australia.
As well as examining the incidence of national notifications and outbreaks, I estimated the
burden of domestically acquired illness in the Australian community, taking into account
underreporting. Circa 2015, I estimated 90,833 (90% CrI 51,583-158,256) cases of non-
typhoidal Salmonella. This is a 49% increase in the estimated rate of salmonellosis cases
since 2010 due to all non-typhoidal Salmonella (Kirk et al., 2014), reflecting an increase in the
national number of notifications from 2013–2015, compared with 2006–2010 (Department of
Health, 2019). This confirms that the burden of Salmonella incidence the Australian community
is comparatively high and is increasing.
The community estimates also show that salmonellosis can be severe, resulting in 4,312 (90%
3,335-11,091) hospitalizations. This is a 38% increase in the rate of estimated hospitalizations
from circa 2010 (Kirk et al., 2014), reflecting an increase in the number of hospitalizations
reported by the Australian Institute of Health and Welfare from 2011–12 to 2014–15 (AIHW,
2016), with 2006–2010 hospitalization data. The estimate suggests that approximately 5% of
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reported salmonellosis cases result in hospitalization, compared to my finding that 15% of
cases in salmonellosis outbreaks over 2001–2016 were hospitalized (with varying
hospitalization rates by serotype). This indicates that illness in outbreaks may be more severe
than sporadic illness, the lower proportion of hospitalizations in the community may reflect an
average proportion across different serotypes (whereas the outbreak proportion is largely
driven by the Salmonella Typhimurium hospitalization rate), or that the community estimates
may underestimate hospitalization numbers.
I estimated that there were 6,133 (90% CrI 3,335-11,091) cases of IBS and 6,080 (90% CrI
1,420-15,959) cases of ReA following salmonellosis circa 2015. Additionally, I estimated 19
(90% CrI 15-22) deaths due to Salmonella circa 2015, a conservative estimate that only
increased about 5% from circa 2010. This is due to the fact that I was unable to get updated
mortality data and had to adjust the 2001–2010 data for the 2015 population. Despite this
limitation, the number of hospitalizations, sequelae, and deaths from Salmonella in the
community circa 2015 are high.
In addition to finding that Salmonella is increasing, I showed that there are geographic
differences in the rates of infection, trends over time, and serotypes causing infection. While
states and territories with tropical climatic zones (Northern Territory, Queensland, and
Western Australia) had some of the lowest estimated annual increases, they had the highest
rates of infection. In addition, these states and territories, along with the island state Tasmania,
had a higher proportion of notifications that were non-Typhimurium Salmonella. This supports
research that environmental factors are important for survival of certain Salmonella serotypes
(Akil et.al. 2014; Finn et al., 2013; Martinez-Urtaza et al., 2004; Milazzo et al., 2016; Stephen
and Barnett, 2016) and implies that different interventions to prevent and control infection for
different geographic regions are likely important for reducing the rates of infection.
I found that 79% of reported salmonellosis outbreaks in Australia over 2000–2016 were of
foodborne or suspected foodborne transmission, with 84% of these due to Salmonella
Typhimurium. Salmonella Typhimurium was the most commonly notified serotype in Australia,
responsible for over 40% of notifications over 2000–2013. With 72% of Salmonella infections
(Vally et al., 2014) and 79% of outbreaks in Australia estimated to be transmitted through
contaminated food, prevention and control measures along the food chain need to be
improved to reduce rates of infection and outbreaks, particularly rates of Salmonella
Typhimurium.
From my work, it is clear that eggs are an important source of salmonellosis in Australia. In
investigating the food vehicles associated with Salmonella outbreaks in Australia, I found that
eggs and egg-containing foods were the responsible food vehicle in 50% of the 476 (61%)
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foodborne or suspected foodborne outbreaks where a food vehicle was listed. While eggs
have also been identified as an important cause of Salmonella outbreaks in the USA and
Canada (Belanger et al., 2005; Jackson et al., 2013), the proportion of outbreaks where eggs
were the reported food vehicle was higher in Australia, with S. Typhimurium the responsible
serotype in 95% of these outbreaks. I also identified eggs as an important source of
Salmonella Typhimurium cases in the Australian Capital Territory through a case-case
analysis of WGS clusters and an investigation of several outbreaks of one MLVA pattern
associated with eggs. These findings support a previous study, which showed an increasing
proportion of foodborne Salmonella outbreaks linked to eggs over 2001–2011, with 90%
caused by Salmonella Typhimurium (Moffatt et al., 2016). While control measures across the
egg supply chain have been implemented in Australia over the last several years, the high
proportion of outbreaks due to eggs implies that more needs to be done to prevent egg-related
salmonellosis. There is hope that the recent introduction of the vaccination of laying flocks for
Salmonella Typhimurium will help to reduce the burden of egg-related illness (Groves et al.,
2016; McWhorter and Chousalkar, 2018).
In this thesis, I identified other key food vehicles of Salmonella infection. While these key food
vehicles may not be representative of the food sources in all foodborne outbreaks, and less-
commonly associated foods may not always be identified by investigators, identifying these
help to target food safety standards and policies. There were few outbreaks associated with
sprouts, nuts, fruit, and some fresh salad produce over 2001–2016, however these outbreaks
tended to be larger than outbreaks associated with many other food vehicles, likely due to the
wide distribution of these food products. This finding implies that food safety standards and
policies targeted at the foods causing large outbreaks may be important to prevent
salmonellosis associated with fresh produce.
Although most Salmonella infections are transmitted through contaminated food, I showed
that wildlife and the environment can be an important reservoir of infection for some serotypes.
I found that wild birds are a likely reservoir for Salmonella Typhimurium DT160 infection, while
Salmonella Mississippi is endemic with a broad range of host reservoirs in the Tasmanian
environment. Epidemiological investigations for these serotypes should be focused on
environmental and animal risk factors, in order to target specific sources for prevention and
policy measures.
Costs of illness and costs of WGS
A main finding of my thesis is that Salmonella illness results in substantial costs to the
Australian society. I estimated that circa 2015, Salmonella in Australia cost AUD 124.4 million
(90% CrI 107.4-143.1 million), or AUD 146.8 million (90% CrI 127.8-167.9 million) when IBS
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and ReA following Salmonella infection were included. As 72% of salmonellosis is estimated
to be transmitted through contaminated food (Valley et al., 2014), the burden from foodborne
Salmonella illness alone is estimated to cost AUD 88.9 million (90% CrI 63.9-112.4 million)
and AUD 104.8 million (90% CrI 75.5-132.3 million) with costs for IBS and ReA. As costs
associated with foodborne illness make up most of the overall cost, targeted interventions
across the food chain to reduce salmonellosis would help to reduce costs.
I estimated the costs of illness as costs for health care usage, lost productivity, and premature
mortality by 4 age groups, showing the contribution of direct and indirect costs to the total cost.
Examining where costs are highest can indicate the most beneficial areas for potential
intervention. For example, the highest cost per case was for those in the 65 years and older
age group, particularly costs associated with health care use and premature mortality.
Therefore, reducing illness in this group would have a significant impact on reducing overall
costs. Reducing illness in those 65 years and older could include addressing identified risk
factors including proton pump inhibitor use, high chicken consumption, and environmental
exposures related to rural and remote living (Chen et al., 2016), as well as strengthening food
safety and infection control policies in aged care facilities (Kirk et al., 2008).
These much-needed estimates fill a gap in the literature by quantifying the costs of
salmonellosis and foodborne salmonellosis in Australia. As reducing Salmonella
contamination in foods, animals, and the environment can be costly, these estimates will help
to quantify the economic trade-offs for controlling salmonellosis in different environments
(McLinden et al., 2014; Roberts, 1988). In particular, those working on Australia’s Foodborne
Illness Reduction Strategy 2018–2021+ (Food Regulation, 2018), can use these estimates to
quantify the effects of certain actions at reducing illness, helping to prioritize interventions and
policies.
I used the costs of illness estimates in this thesis to assess the costs of WGS in terms of how
the technology may assist public health action. I found that WGS data would need to prevent
approximately 275 (2%) of all notified cultured Salmonella cases each year to be cost-equal
to traditional typing methods, or 1,550 (10%) of notified Salmonella cases to be cost-equal to
PCR in Australia in 2018. WGS has potential to save significant amounts of money in
prolonged outbreaks if data can be used to detect outbreaks and implement interventions
earlier. My findings are in line with a recent Canadian economic analysis of Salmonella
detection in fresh produce, poultry, and eggs using WGS, which found that WGS will result in
a net benefit of millions of dollars (Jain et al., 2019). My analysis is an important piece of
evidence as Australia and other countries consider transitioning completely to WGS for routine
surveillance of Salmonella and other foodborne disease pathogens.
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Impacts of WGS on surveillance and outbreak detection
A key finding of this thesis is the value of WGS data in showing the relatedness of cases’
Salmonella isolates. WGS linked an additional 9% of Salmonella Typhimurium isolates in the
Australian Capital Territory thought to be sporadic to at least one other isolate, compared with
MLVA and epidemiological data. WGS data also showed the relatedness of Salmonella
Typhimurium DT160 and Salmonella Mississippi isolates in Tasmania and New Zealand and
confirmed that cases from seven point-source Salmonella Typhimurium outbreaks occurring
across a wide geographic area were related. The greater sensitivity and specificity of WGS
data compared to traditional typing methods increases the speed at which outbreaks can be
detected and provides more detail for the outbreaks to be understood (WHO, 2018).
Therefore, this accurate, robust, reliable and high throughput typing method (Ashton et al.,
2016) is useful in responding to threats quickly, with the ultimate aim of controlling and
preventing infection.
WGS can also be useful in detecting antimicrobial resistance in Salmonella isolates, tracking
changes in microbial populations, detecting resistant strains of public health importance,
informing clinical therapy decisions, guiding policy recommendations, and assessing the
impact of resistance containment interventions (McDermott et al., 2016; WHO, 2019). The
Salmonella isolates sequenced for my thesis had little antimicrobial resistance detected. There
was one Salmonella Mississippi isolate with blaTEM-1 gene that mediates resistance to
ampicillin. While there is an increasing incidence of antimicrobial resistance in Salmonella
isolates in Australia, the finding of low levels of resistance in this thesis is likely due to the low
prevalence of resistance in S. Typhimurium, the fact that many multi-drug resistant Salmonella
were related to overseas travel, and a conservative use of antibiotics in Australian food
animals (Australian Government, 2017; Williamson et al., 2018).
In this thesis, I show the value of linking human cases to food, environmental, and animal
sources. Not only can WGS show the relatedness of isolates from food vehicles to human
cases, but it can also provide more detail on human cases to help statistically associate food
vehicles and illness (Byrne et al., 2014; Inns et al., 2017; Waldram et al., 2018). Although no
Salmonella Typhimurium was detected on eggs, at the egg grading facility, or on an egg farm
to link it to the human cases in my study of seven point-source outbreaks, WGS did show that
isolates from foods positive for Salmonella in one of the outbreaks (likely contaminated
through cross contamination) were highly related to human outbreak cases. WGS data also
elucidated animal and environmental reservoirs for DT160 and Mississippi, particularly when
combined with epidemiological data. Human and sparrow DT160 isolates were genetically
related, with a high proportion of cases reporting direct contact with animals. The genetic
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heterogeneity of Salmonella Mississippi isolates was mirrored in the fact that no risk factors
were significantly higher for Salmonella Mississippi cases compared to DT160 cases,
suggesting multiple potential host reservoirs. Real-time sequencing of Salmonella could help
monitor emergence and identify clusters, enabling epidemiologists to more accurately identify
common risk factors and aid in source attribution.
My thesis includes seminal research on the prospective use of WGS for surveillance of
Salmonella Typhimurium in a small public health unit. While WGS had been used for
surveillance and outbreak investigation prior to this study, nothing had been published on
using the data effectively at a local level for these purposes. I identified several issues to
consider when implementing routine WGS for Salmonella surveillance in a public health unit,
including timeliness, national harmonization, integration of sequence with epidemiological
data, and integration of food and environmental sequence data with human data. WGS will be
most effective if data are received by the public health unit in a timely manner, so that risk
factor data for related cases can be obtained and public health action can be implemented
when a source of illness or outbreak is detected.
National harmonization of sequence data and Salmonella surveillance are key to effective use
of WGS data for surveillance and outbreak investigations. As Australian public health
reference laboratories are state-based, this work was novel in that it required two state
reference laboratories to routinely share sequence data using a virtual machine and a single
bioinformatic pipeline for analysis. My work has highlighted the importance of a sustainable
system for the sharing of standardized data and analysis among public health laboratories and
state health departments nationally. As I found highly related Salmonella isolates across large
geographic areas in Australia, and highly related Salmonella isolates have been found across
countries (Inns et al., 2017), WGS data needs to be shared and surveillance harmonized in
order to detect and investigate these widespread outbreaks.
I identified difficulties in integrating WGS data with epidemiological data, as public health units’
surveillance databases did not have the capacity to store and use WGS data. Overlaying and
analysing these two data sets together was time consuming without a fit-for-purpose computer
program. Although I used programs like Phandango (https://jameshadfield.github.io/phandango/#/),
Figtree (http://tree.bio.ed.ac.uk/software/figtree/), Microreact (https://microreact.org/), and iTOL
(https://itol.embl.de/) to integrate and visualize the data, I was unable to identify one accessible
program that could easily integrate the data and visualize all risk factors of infection among
WGS-based clusters. In addition, public health unit staff required additional training to use and
understand WGS data to detect and investigate outbreaks. Ideally, resources should be devoted
to the development and training of an integrated surveillance system that can identify WGS
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clusters of human and non-human isolates and allow for the input and visualization of
epidemiological information, including risk factor data.
As I have shown with Salmonella Typhimurium outbreaks, DT160, and Salmonella Mississippi,
not only is it important to integrate human sequence data and epidemiological data, but
integrating food, environmental, and animal sequence data can also help to elucidate food
vehicles and animal or environmental reservoirs of infection. While integrated surveillance is
resource-intensive, it provides comprehensive information for surveillance and greatly
improves the ability to rapidly trace sources of contamination and estimate the relative
contribution of different sources to human infection (WHO, 2018). The high discriminatory
power of WGS data will be extremely useful in integrated surveillance systems and particularly
helpful when WGS data detects small clusters where epidemiological links are obscured.
However, integrated surveillance requires the willingness and capacity for cross-sectoral data
sharing, which is something to work towards in Australia.
8.2 The future of Salmonella surveillance and research in Australia
Since the start of my PhD, the epidemiology of Salmonella in Australia has begun to change.
National notification rates, which steadily increased from 49.1 cases per 100,000 in 2012 to
74.7 cases per 100,000 in 2016, dropped to 66.7 cases and then to 57.6 cases per 100,000
in 2017 and 2018 respectively (Department of Health, 2019). Not only have rates dropped
since 2016, but the proportion of Salmonella Typhimurium notifications has also decreased
from between 44% and 48% over 2012–2015 to 33% in 2016 and 35% in 2017 (Department
of Health, 2019). As my findings show that eggs are the main food vehicle in Salmonella
Typhimurium outbreaks, the egg industry and some food regulators have attributed the
decrease in Salmonella Typhimurium rates to improvements along the egg food chain, in
particular administration of an aroA-deletion live Salmonella Typhimurium vaccine in layer
flocks and the Egg Standards of Australia quality assurance program (Druce, 2018; Groves et
al., 2016, 2017).
Alongside this decrease in notifications, and the proportion of notifications that are Salmonella
Typhimurium, there has recently been an increase in notifications of domestically-acquired
Salmonella Enteritidis (Australian Associated Press, 2019; “More egg recalls”, 2019; NSW
Health, 2019). While the New South Wales Department of Primary Industry states that the
Australian egg industry is free from Salmonella Enteritidis, between May 2018 and March
2019, a total of 149 New South Wales residents, and additional cases in Victoria, Queensland
and Tasmania, were reported to be unwell following a Salmonella Enteritidis outbreak linked
to contaminated eggs (FSANZ, 2019; NSW Department of Primary Industries, n.d.; NSW
Health, 2019). This may be an example of how controlling one Salmonella serotype can lead
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to the emergence of another serotype to fill the niche left by those control measures (Cogan
and Humphrey, 2003). Continued monitoring and research on the emergence of Salmonella
Enteritidis in Australia will be necessary for understanding and controlling infection. WGS will
be an important tool in this monitoring to help determine lineage, detect outbreaks, and identify
sources of infection.
WGS is revolutionizing public health surveillance of Salmonella in Australia. The use of WGS
data requires changes, including new or adapted systems and tools for storing and analysing
information for surveillance purposes. WGS also requires collaboration unlike previous typing
methods have, with epidemiologists, microbiologists and bioinformaticians working closely
together, as well as increased communication and harmonization among public health
laboratories and public health departments across different jurisdictions. In addition,
communication and collaboration globally has become more important, as WGS can help to
break down borders making global surveillance of foodborne illness easier with standardized
and shared data. By offering highly discriminatory data for human cases, as well as for
reservoirs and vehicles of infection, real-time national and integrated WGS data will ultimately
improve the speed and effectiveness of public health action.
In my thesis, I have highlighted areas of future research that could assist in understanding the
epidemiology of Salmonella in Australia, with the ultimate aim to control and prevent illness.
Further research on the sources of Salmonella illness, particularly for emerging or high
incidence serotypes would be useful. I have described the vehicles of infection related to
Salmonella outbreaks, but it is unknown whether these are the same vehicles causing
sporadic infection. Serotype specific case control studies in the community would help to
identify vehicles for sporadic infection, providing evidence beyond outbreak studies for the
implementation of control measures. WGS strain-specific case control studies may also be
possible and useful in the future if a particular strain is widespread in the community.
My cost of illness estimates for Salmonella offer the opportunity for further research on the
cost effectiveness of different interventions, both along the food supply chain, and at the
surveillance level (e.g. WGS). The methods I used to calculate the number of cases that need
to be prevented for WGS to be cost-equal and the potential cost-savings using WGS in
outbreak scenarios can be applied to other countries and other foodborne pathogens as they
consider transitioning to WGS for surveillance. Future research on the costs of salmonellosis
to industry and trade would also be helpful in quantifying the full burden of Salmonella in
Australia.
For a genetically heterogeneous serotype such as Salmonella Mississippi, which likely has a
multiple potential host reservoirs, Bayesian source attribution research using WGS data could
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prove helpful in identifying the relative importance of different host reservoirs and sources of
infection. While there have been few published Bayesian source attribution studies using
WGS, one study concludes that WGS is transforming source attribution studies and provides
guidance on the interpretation of WGS data (Pightling et al., 2018). A major source attribution
study for Campylobacter in New Zealand initiated a sentinel surveillance site and evidence for
the advocacy of more rigorous controls on foodborne pathways, helping to more than halve
notification rates (Sears et al., 2011). Access to farm or producer level Salmonella data for
source attribution studies would be the most useful for identifying sources of infection and
implementing prevention and control measures.
8.3 Conclusion
The findings in this thesis increases Australian agencies’ understanding of the epidemiology
of non-typhoidal Salmonella. My thesis has made a unique contribution to the knowledge
around effective and actionable use of WGS data for public health surveillance and outbreak
investigation of Salmonella. I have provided justification for routine use of sequencing by
finding that WGS data is sensitive, specific, can help detect and solve outbreaks, elucidates
sources of infection, and could result in significant cost-savings. I found that Salmonella,
particularly infections transmitted through contaminated food, have been an increasing and
costly problem in Australia. While recent control measures, including vaccination and changes
in the egg industry appear to have reduced rates of serotype Typhimurium, future efforts
should focus on control measures over multiple food vehicles, environmental sources, and
strains. Monitoring emerging strains will also be imperative. WGS is a revolutionary tool that
will enhance public health surveillance and outbreak investigations, hopefully reducing rates
of infection in Australia.
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Appendix 1. Supplementary materials for chapter 3 The following supplementary materials were part of the manuscript submission and published
online as a supplement to the paper
Ford L, Glass K, Veitch M, Wardell R, Polkinghorne B, Dobbins T, Lal A, Kirk MD. Increasing
incidence of Salmonella in Australia, 2000-2013. PLoS One. 2016;11(10): e0163989, doi:
10.1371/journal.pone.0163989.
S1 Table. Number and proportion of Salmonella notifications without serovar data by state and
territory, Australia 2000-2013
State Number of notifications
without serovar data
Total number of
notifications
Proportion of notifications
without serovar data (%)
ACT 23 2,028 1.1
NSW 1,355 34,100 4.0
NT 189 5,850 3.2
Qld 819 35,597 2.3
SA 57 9,465 0.6
Tas. 49 2,772 1.8
Vic. 209 24,122 0.9
WA 259 13,261 2.0
Total 2,960 127,195 2.3
S2 Table. Salmonella spp. cases each year, the proportion of cases excluded due to missing
serovar, age or sex data, crude notification rate after exclusions, S. Typhimurium notification
rate, and Non-Typhimurium notification rate (per 100,000 persons, Australia 2000–2013).
Year Total cases
(n)
Proportion
excluded
(%)
Crude rate
(per 100,000
persons)
S. Typhimurium
rate (per 100,000
persons)
Non-Typhimurium
rate (per 100,000
persons)
2000 6,154 5.2 30.6 12.4 18.3
2001 6,995 3.8 34.9 13.7 21.3
2002 7,824 2.9 39.0 15.7 23.2
2003 6,948 3.4 34.1 14.4 19.7
2004 7,752 2.3 38.0 14.8 23.2
2005 8,346 2.0 40.5 16.9 23.6
106
2006 8,168 1.9 39.2 14.0 25.2
2007 9,398 1.7 44.3 19.8 24.5
2008 8,234 2.4 37.8 16.7 21.1
2009 9,443 2.8 42.3 18.3 24.0
2010 11,828 2.7 52.3 24.0 28.2
2011 12,209 1.7 53.7 27.1 26.7
2012 11,178 2.5 48.0 23.2 24.8
2013 12,718 3.6 53.0 25.8 27.2
S3 Table. Proportion (%) of S. Typhimurium and the 20 most notified non-Typhimurium
Salmonella serovars of total notifications included in this study for each state and territory,
Australia, 2000-2013.
ACT NSW NT Qld SA Tas. Vic. WA
Typhimurium 64.1 55.7 10.7 27.0 58.6 35.8 60.3 32.0
Enteritidis 4.7 4.4 2.0 4.1 5.0 3.6 5.7 15.5
Virchow 3.0 3.5 5.9 11.6 2.2 1.7 3.0 1.4
Saintpaul 1.8 1.9 9.3 8.4 1.9 1.2 1.7 4.6
Birkenhead 0.5 3.4 <0.1 4.9 0.1 <0.1 0.4 0.1
Infantis 2.0 2.7 2.1 0.7 3.9 1.1 2.6 2.0
Paratyphi B bv Java 1.9 2.1 2.4 1.4 1.4 1.0 1.9 3.4
Chester 0.6 1.2 3.2 2.7 2.2 0.6 0.7 2.9
Muenchen 0.8 0.9 2.8 2.2 1.4 0.3 0.5 2.9
Bovismorbificans 1.6 2.1 0.5 0.9 2.3 0.9 1.5 1.1
Aberdeen 0.1 0.3 1.3 4.1 0.1 0.2 0.3 0.1
Hvittingfoss 0.6 0.5 1.1 3.3 0.2 0.1 0.6 0.4
Stanley 1.7 1.3 0.3 0.7 1.0 1.2 1.8 1.7
Mississippi 0.3 0.2 0.1 0.2 0.2 41.9 0.5 0.1
Waycross 0.1 1.0 0.1 2.8 0.1 <0.1 0.1 <0.1
Weltevreden 0.7 0.6 3.3 1.2 0.5 0.3 0.7 1.1
Anatum 0.2 0.4 2.7 1.3 1.0 0.2 0.4 1.6
Agona 0.8 1.0 0.6 0.9 1.0 0.6 0.8 0.8
Newport 0.8 0.7 0.3 0.4 1.1 1.1 1.5 1.1
Singapore 0.5 1.3 0.2 0.4 0.8 0.2 0.6 1.2
Potsdam 0.6 0.6 0.4 1.1 0.6 0.7 0.3 0.6
S1
Fig
. Sta
te a
nd
ter
rito
ry c
rud
e (d
ots
) an
d p
red
icte
d (
lines
wit
h 9
5% C
I) n
oti
fica
tio
n r
ates
per
100
,000
per
son
s, A
ust
ralia
200
0-2
013
107
S2 Fig. Salmonella Typhimurium and non-Typhimurium predicted notification rates per
100,000 (with 95% CI) by age group for each State and Territory, 2000-2013
0
20
40
60
80
100
120
140
160
No
tifi
cati
on
ra
te p
er 1
00
,00
0
ACT
Typhimurium
Non-Typhimurium
0
200
400
600
800
1000
1200
1400
No
tifi
cati
on
ra
te p
er 1
00
,00
0
NT
Typhimurium
Non-Typhimurium
0
20
40
60
80
100
120
140
160
No
tifi
cati
on
ra
te p
er 1
00
,00
0
NSW
Typhimurium
Non-Typhimurium
111
0
50
100
150
200
250
300
350
400
450
500N
oti
fica
tio
n r
ate
per
10
0,0
00
QLD
Typhimurium
Non-Typhimurium
0
20
40
60
80
100
120
140
160
180
200
No
tifi
cati
on
ra
te p
er 1
00
,00
0
SA
Typhimurium
Non-Typhimurium
0
50
100
150
200
250
300
No
tifi
cati
on
ra
te p
er 1
00
,00
0
TAS
Typhimurium
Non-Typhimurium
112
0
50
100
150
200
250
300
No
tifi
cati
on
ra
te p
er 1
00
,00
0
WA
Typhimurium
Non-Typhimurium
0
20
40
60
80
100
120
140
No
tifi
cati
on
ra
te p
er 1
00
,00
0
VIC
Typhimurium
Non-Typhimirium
113
114
Appendix 2. Supplementary materials for chapter 4 The following supplementary materials were part of the manuscript submission and published
online as a supplement to the paper
Ford L, Moffatt C, Fearnley E, Sloan-Gardner T, Miller M, Polkinghorne B, Franklin N,
Williamson DA, Glass K, Kirk MD. The epidemiology of Salmonella outbreaks in Australia,
2001-2016. Frontiers in Sustainable Food Systems. 2018;issue:page, doi:
10.3389/fsufs.2018.00086.
Supplementary Information 1
S1 Table 1: Outbreak setting definitions
Setting Definition
Food premises Food prepared in restaurants, takeaway stores, bakeries,
commercial caterers, national franchised fast food stores, grocery
stores, delicatessens, airlines, or cruises
Home kitchens Food prepared in private residences
Institutions Food prepared in aged care facility, hospital or medical centre,
school, child care centre, military institution, camps, or other
institution not otherwise specified
Market, fair/festival,
or mobile service
Food prepared in markets, fairs, festivals, food trucks, or other
temporary or mobile services
Commercially
manufactured food
Food that is manufactured and distributed commercially
Imported food Imported ready-to-eat food product
Primary produce Food grown and harvested that is typically consumed with no or
minimal cooking or further processing
Other Picnic or other setting not specified
Unknown Setting food prepared in is not known
S1 Table 2: Food categories for salmonellosis outbreaks in Australia
Egg sauces Mayonnaise
Raw egg mayonnaise
Dill mayonnaise
Raw egg mayonnaise in chicken sandwiches
Chicken salad with raw egg mayonnaise
Pork/chicken and salad rolls (with raw egg mayonnaise)
Potato salad with raw egg mayonnaise
Hamburgers with homemade mayonnaise
Raw egg mayonnaise and raw egg milkshakes
Raw egg aioli
Citrus aioli
Garlic aioli
Aioli and mayonnaise-based sauces
Coleslaw with raw egg aioli
Tartare sauce
Tartare sauce, prepared with raw egg
Mayonnaise/tartare/aioli
Raw-egg mayonnaise; raw-egg tartare sauce
Chicken Caesar roll containing raw egg mayonnaise
Caesar salad dressing
Caesar salad dressing with raw egg
Aioli and Caesar salad
Raw egg mayonnaise/Caesar salad dressing
Raw egg salad dressing
Raw egg dressing
Béarnaise sauce
115
Eggs Benedict
Eggs benedict with potato rosti
Eggs benedict; hollandaise sauce
Egg and/or hollandaise sauce
Hollandaise sauce
Raw egg hollandaise sauce
Egg and/or hollandaise sauce
Raw egg sauces
Egg-based sauce
Cold emulsion (raw egg white containing)
Raw egg chipotle cream
Bánh mì (Vietnamese
style sandwiches)
Vietnamese rolls with raw egg butter
Raw egg butter on Vietnamese roll
Vietnamese rolls
Vietnamese-style rolls
Vietnamese pork roll
Pork Rolls (raw egg butter)
Pork rolls with raw egg mayonnaise
Vietnamese pork/chicken/salad rolls containing raw egg
butter
Desserts containing raw
or lightly cooked eggs
Chocolate Mousse
White chocolate mousse
Chocolate mousse with raw eggs
Chocolate mousse cake
Raw egg chocolate mousse cake
Pizza containing egg and chocolate mousse containing raw
egg
Tiramisu containing raw eggs
Tiramisu
Fried ice cream
Deep fried Ice cream containing minimally cooked raw eggs
Fried ice cream with raw egg
Deep fried ice-cream balls
Egg coated fried ice cream
suspect pork in plum sauce, fried ice cream
Homemade ice cream
Ice cream containing raw eggs
Ice cream cake with raw eggs
Raw egg milkshake
Raw egg smoothies
Raw egg semifreddo
Custard
Dessert containing raw egg custard
Custard fruit tart
Bread and butter pudding
Frozen ice cream sponge mixture
Pancake batter
Pancake batter containing raw eggs
Cream and custard profiterole cakes
Chocolate cake with raw egg meringue
116
Chocolate fondant
Rum and raisin bread cake with custard
Raw egg cake mix
French Toast
Various bakery products (custard buns)
Bomb Alaska
Trifle/jelly; Bomb Alaska
Crepes
Custard Berliner bun
Custard eclairs and custard cannoli
Raw brownie batter
Hedgehog - eggs cookie dough raw
Hazelnut gateau with raw egg mousse filling
Dessert containing raw eggs suspected
Dessert containing lightly cooked eggs
Uncooked muffin batter
Pastry custard tart with strawberries & jelly glaze
Eggs used to make cake filling
Desserts, other Chocolate milk (& other foods)
commercial ice cream with homemade chocolate sauce
Cheesecake
Cold set cheesecake
Chocolate eclairs; cream puffs; various cakes; various
bakery products
Engagement cake – cream
Cream filled cakes
Cheese or cream cake
Layered chocolate cake, prepared with cream and ganache
icing (no raw eggs used)
Desserts
Profiteroles
Trifle
Banana Milkshake
Mango pudding dessert
Apple turnover
Bakery products (various)
Egg based bakery products
Bakery cakes and buns
Vietnamese bakery goods
Bakery products, no specific item identified
Various bakery products
Numerous bakery goods
Desserts (containing eggs)
117
Eggs, other Egg nog
Egg wash
Raw eggs
Suspected raw egg
Eggs
Egg shell rinse and contents of cracked eggs
Suspected eggs
Free-range eggs
Raw or runny eggs
Boiled eggs
Scrambled eggs
Eggs (fried soft)
Poached eggs
Egg containing food
Eggs used in uncooked and lightly cooked foods
Menu items containing undercooked egg
Egg dishes
Raw egg dish
Egg dish with cous cous
Asparagus egg surprise dish
Frittata
Breadcrumbs, breakfast eggs served a number of ways
Suspect cross contamination from egg
Sprouts Mung bean sprouts
Snow pea sprouts
Alfalfa sprouts
Poultry Chicken liver pâté
Chicken breast cooked in the home
Chicken
Possibly chicken pieces from franchised restaurant
Roast chicken pieces served cold
Suspected fluid thickener contaminated by raw chicken
mince
Chicken burger
Warm chicken salad
Marinated chicken roll
Suspected BBQ chicken
Chicken (Home BBQ)
Grilled chicken
Chicken suspected
Chicken and gravy
Roasted chicken
Suspect chicken spring rolls
Chicken and pasta salad
Baked chicken
Sticky rice balls with chicken
Chicken meat
Unknown, possible chicken based dish
Chicken meal
Duck prosciutto
118
Raw pigeon meat
Duck parfait
Duck pancakes
Duck liver pâté
Roast duck
Pork Pork suspected
Suspected roast pork
Roast pork
Barbecued pork
Pork spit roast
Sliced Virginian ham
Pork Salami
Spit roasted Pork
Capocollo (cured pork)
Salami
Slow cooked pork hock
Leg of Ham
Homemade unfermented sausage
Fish Ling fish fillets
Fish cakes
Chinese style minced fish balls
Suspected salmon & couscous dish
Barramundi spring rolls
Lamb Lambs liver
Offal (lamb intestine)
Offal stew (lamb intestine, tripe, liver and kidney)
Lambs fry with bacon, onions & gravy
Lamb shanks or salad
Beef Roast meat
Beef burger
Silverside
Beef wraps
Suspect beef products
Frozen raw meat burgers, raw beef steak
Nuts Peanuts
Suspected peanut/cashew mixture
Raw Almonds
Fruit Rockmelon
Pawpaw
Salad, other Assorted salads
Thai salad
Rice salad
Suspect salad
Caesar salad
Chicken Caesar Salad
Potato Salad
Pasta salad
Sweet potato and feta cheese salad
Multiple salads
Crustacean/Mollusc Crab
119
Prawn Soup
Calamari
Prawn salad rolls
Suspect oysters
Vegetables Fresh chillies used to prepare chilli sauce
Taro
Bagged salad products
Suspected cucumber
Sushi Sushi Rolls
Korean Sushi
Sushi (unspecified)
Kimbap style sushi
Tuna and salmon sushi rolls
Tuna mix for sushi
Chicken hand rolls
Sandwich, other Sandwiches
Premade sandwiches
Pork roll, salad roll, sandwiches
Pork/Chicken rolls from bakery
Bread rolls with different fillings
Sandwich containing egg and ham
Egg and bacon roll
Bacon and egg burger
Suspect beef or chicken hamburger with salad, cheese, bacon
Sandwich containing egg and ham
Suspected gourmet rolls including red onion
Chicken and lamb souvlakis
Chicken salad pita bread wrap (using iceberg lettuce)
Pork rolls
Suspected pork rolls
Egg and lettuce sandwich
Kebabs
Pasta Uncooked pasta dough containing eggs
Ravioli
Pasta with lightly cooked egg
Suspected under cooked eggs in pasta dish
Pasta Carbonara
Pasta with raw egg
Tahini/helva Tahini
Imported tahini
Imported helva
Dips Dips
Pesto made with basil, garlic, olive oil
Suspect dip – salad dip and baba ganoush dip
Mixed foods Mayonnaise, chicken
Chicken and fried ice cream
Passionfruit cheesecake; meat pies
Salty fish, pork and egg dish
Baked beans and/or chilli con carne
Hummus and tabouli
120
Fried rice
Chinese food
Variety of Chinese foods
Takeaway chicken, rice, coleslaw, potatoes
Plain hamburger; egg
Chicken; eggs
Chicken, hummus, tabouli
Suspected eggs or chicken
Cooked pork mince and leftover food (mix of tofu, rice,
duck)
Probably prawn dumplings prepared with minced prawn,
Coriander and egg to bind
Salmon/egg/onion/rice patties
Lamb tartare with raw egg
Chicken long soup (with egg and chicken)
Egg-battered chicken and veal schnitzels
Potato bake, lemon meringue, chicken patty
Rice paper rolls
Beef appetiser or frittata
Broken Rice
Noodle dish with chicken and egg
Chicken teriyaki or scrambled eggs
Meals containing chicken pieces and pizza of any kind
Prawn/noodle dish (lightly cooked eggs)
Nasi-Lemak
Suspect steak; suspect fried rice
Combination Chinese omelette
Egg nog or undercooked chicken
Mixed spit roasted meats
Eye fillet meal with onions, potato, salsa verde and red wine
jus
Banana smoothie; Berry smoothie; Any fish
Multiple, likely initial contamination from eggs
Meat based potato pie, rice pudding (both containing raw
eggs)
Multiple foods - hummus and aioli positive
Multiple foods, including sliced deli meats
Undetermined Mixed dishes
Multiple foods
Cordial?
Prawn paste? Tofu eggplant dish
Probably pureed food
Suspected to be ready to eat food such as hand cut fruit and
Pre-prepared meals
Contaminated premade product
Buffet breakfast
Vitamised and soft foods
Various salad rolls from bakery; meals prepared at home
containing egg
Vitamised food
121
Gravy
Unknown pureed food
Contaminated premade products
Unknown, probably assorted salads, wraps and burgers
Unknown, possibly minced or pureed diet
Unknown Unknown
Not identified
Not detected
No vehicle identified
999
None implicated
N/A
Unknown, possible a food source or person-to-person
transmission and then further spread by person.
122
Typhimurium Agona Anatum Bareilly Birkenhead BovismorbificansRaw egg desserts 103 0 0 0 0 0Egg-based sauce 76 0 0 0 0 0Eggs, other 41 0 0 0 0 0Mixed dishes 33 0 0 0 0 0Poultry 28 0 1 0 0 0Sandwiches, other 18 0 1 0 0 1Desserts, other 23 0 0 0 0 0Vietnamese Rolls 17 0 0 0 0 0Pork 9 0 0 0 0 1Salads 8 0 1 0 0 0Sushi 5 1 0 1 0 0Beef 4 0 0 0 0 0Pasta 6 0 0 0 0 0Lamb 3 0 0 0 0 0Fish 4 0 0 0 0 0Sprouts 0 0 0 0 0 0Crustacean/ Mollusc 3 0 0 0 0 0Fruits 0 0 0 0 0 0Vegetables 0 0 1 0 0 0Tahini or helva 1 0 0 0 0 0Dips 3 0 0 0 0 0Nuts 2 0 0 0 0 0Undetermined 23 0 0 0 1 1Total 410 1 4 1 1 3
S2 Table 1: Number of foodborne and suspected foodborne salmonellosis outbreaks with statistical, laboratory or descriptive evidence by serotype, 2001-2016, Australia
123
Raw egg dessertsEgg-based sauceEggs, otherMixed dishesPoultrySandwiches, otherDesserts, otherVietnamese RollsPorkSaladsSushiBeefPastaLambFishSproutsCrustacean/ MolluscFruitsVegetablesTahini or helvaDipsNutsUndeterminedTotal
Enteritidis Chester Hadar Hessarek Hvittingfoss Infantis Johannesburg0 0 0 0 0 0 00 0 0 0 0 0 01 0 1 1 0 0 01 0 0 0 0 1 00 0 0 0 0 1 00 0 0 0 0 1 00 0 0 0 0 0 00 0 0 0 0 0 00 0 0 0 0 0 10 0 0 0 0 0 00 0 0 0 0 0 00 0 0 0 0 0 00 0 0 0 0 0 00 2 0 0 0 0 00 0 0 0 0 0 00 0 0 0 0 0 00 0 0 0 0 1 00 0 0 0 1 0 00 1 0 0 0 0 00 0 0 0 0 0 00 0 0 0 0 0 00 0 0 0 0 0 00 0 0 0 1 1 02 3 1 1 2 5 1
124
Raw egg dessertsEgg-based sauceEggs, otherMixed dishesPoultrySandwiches, otherDesserts, otherVietnamese RollsPorkSaladsSushiBeefPastaLambFishSproutsCrustacean/ MolluscFruitsVegetablesTahini or helvaDipsNutsUndeterminedTotal
Kiambu Litchfield Livingstone London Montevideo Mississippi0 0 0 0 0 01 0 0 0 0 00 0 1 0 0 00 0 0 0 1 00 0 0 0 0 00 0 0 0 0 00 0 0 0 0 00 0 0 0 0 00 0 0 1 0 00 0 0 0 0 10 0 0 0 0 00 0 0 0 0 00 0 0 0 0 00 0 0 0 0 00 0 0 0 0 00 0 0 0 0 00 0 0 0 0 10 1 0 0 0 00 1 0 0 0 00 0 0 0 2 00 0 0 0 0 00 0 0 0 0 00 0 0 0 0 01 2 1 1 3 2
125
Raw egg dessertsEgg-based sauceEggs, otherMixed dishesPoultrySandwiches, otherDesserts, otherVietnamese RollsPorkSaladsSushiBeefPastaLambFishSproutsCrustacean/ MolluscFruitsVegetablesTahini or helvaDipsNutsUndeterminedTotal
Muenchen Newport Oranienburg Oslo Potsdam Saintpaul Singapore0 0 0 0 0 1 10 0 0 0 1 0 00 0 0 0 0 1 00 0 0 0 0 0 00 0 0 1 0 0 10 1 0 0 0 0 00 0 0 0 0 0 00 0 0 0 0 0 00 0 0 1 0 0 00 0 0 0 0 0 00 0 0 0 0 0 10 0 0 0 0 0 10 0 0 0 0 0 00 0 0 0 0 0 00 0 0 0 0 1 01 0 2 0 0 2 00 0 0 0 0 0 00 0 0 0 0 2 00 0 0 0 0 0 00 0 0 0 0 0 00 0 0 0 0 0 00 0 0 0 0 0 00 0 0 0 0 0 01 1 2 2 1 7 4
126
Raw egg dessertsEgg-based sauceEggs, otherMixed dishesPoultrySandwiches, otherDesserts, otherVietnamese RollsPorkSaladsSushiBeefPastaLambFishSproutsCrustacean/ MolluscFruitsVegetablesTahini or helvaDipsNutsUndeterminedTotal
Stanley subsp I Virchow Wangata Zanzibar Zanzibar var 15+ Total0 1 0 0 0 0 1060 0 1 0 0 0 790 0 1 0 0 0 470 0 0 0 0 0 360 1 0 0 1 0 340 0 2 0 0 0 240 0 0 0 0 0 230 0 0 0 0 0 170 1 0 1 0 0 150 0 0 0 0 0 100 0 0 0 0 0 80 0 1 0 0 0 60 0 0 0 0 0 60 0 0 0 0 0 50 0 0 0 0 0 50 0 0 0 0 0 50 0 0 0 0 0 50 0 0 0 0 0 40 0 0 0 0 1 40 0 0 0 0 0 30 0 0 0 0 0 31 0 0 0 0 0 31 0 0 0 0 0 282 3 5 1 1 1 476
127
Supplementary Information 3: The number and proportion of outbreaks due to food vehicles
with significant trends over time, Australia, 2001-2016
S3 Table 1: Number and proportion of foodborne or suspected foodborne salmonellosis
outbreaks due to egg-based sauces and Vietnamese style rolls with statistical, laboratory, or
descriptive evidence, Australia, 2001-2016
Number of outbreaks (%)
Egg-based sauces Vietnamese style rolls
2001 0/18 (0) 0/18 (0)
2002 1/16 (6) 0/16 (0)
2003 0/17 (0) 0/17 (0)
2004 1/20 (5) 0/20 (0)
2005 4/24 (17) 0/24 (0)
2006 1/25 (4) 0/25 (0)
2007 5/26 (19) 0/26 (0)
2008 3/23 (13) 0/23 (0)
2009 4/20 (20) 1/20 (5)
2010 7/31 (23) 0/31 (0)
2011 6/33 (18) 2/33 (6)
2012 5/35 (14) 1/35 (3)
2013 10/31 (32) 1/31 (3)
2014 14/60 (23) 6/60 (10)
2015 12/55 (22) 2/55 (4)
2016 6/42 (14) 4/42 (10)
S3 Table 2: Number and proportion of foodborne or suspected foodborne salmonellosis
outbreaks due to poultry, beef, pork, other sandwiches, and other desserts with statistical,
laboratory, or descriptive evidence, Australia, 2001-2016
Number of outbreaks (%)
Poultry Beef Pork Other sandwiches Other desserts
2001 2/18 (11) 2/18 (11) 1/18 (6) 2/18 (11) 1/18 (6)
2002 3/16 (19) 0/16 (0) 1/16 (6) 2/16 (13) 2/16 (13)
2003 3/17 (18) 1/17 (6) 1/17 (6) 1/17 (6) 1/17 (6)
2004 3/20 (15) 0/20 (0) 1/20 (5) 1/20 (5) 1/20 (5)
2005 2/24 (8) 0/24 (0) 1/24 (4) 2/24 (8) 4/24 (17)
2006 1/25 (4) 1/25 (4) 2/25 (8) 2/25 (8) 0/25 (0)
2007 1/26 (4) 0/26 (0) 1/26 (4) 1/26 (4) 3/26 (12)
2008 3/23 (13) 0/23 (0) 1/23 (4) 1/23 (4) 2/23 (9)
2009 0/20 (0) 0/20 (0) 0/20 (0) 1/20 (5) 1/20 (5)
2010 2/31 (6) 0/31 (0) 1/31 (3) 2/31 (6) 1/31 (3)
2011 2/33 (6) 0/33 (0) 1/33 (3) 0/33 (0) 1/33 (3)
2012 1/35 (3) 0/35 (0) 1/35 (3) 3/35 (9) 1/35 (3)
2013 2/31 (6) 0/31 (0) 0/31 (0) 2/31 (6) 1/31 (3)
2014 2/60 (3) 2/60 (3) 2/60 (3) 1/60 (2) 2/60 (3)
2015 5/55 (9) 0/55 (0) 1/55 (2) 2/55 (4) 1/55 (2)
2016 2/42 (5) 0/42 (0) 0/42 (0) 1/42 (2) 1/42 (2)
128
129
Appendix 3. Supplementary materials for chapter 5 The following supplementary materials were part of the manuscript submission as a
supplement to the paper
Ford L, Haywood P, Kirk MD, Lancsar E, Williamson DA, Glass K. Cost of foodborne
Salmonella infections in Australia, 2015. Journal of Food Protection. 2019;82(9):1607-1614,
doi: 10.4315/0362-028X.JFP-19-105.
130
Su
pp
lem
enta
ry m
ate
rial
1:
Hea
lth
car
e u
sag
e va
riab
les,
dat
a so
urc
es, d
istr
ibu
tio
n, a
nd
ou
tpu
t
Age
gro
up: 0
-4 y
ears
Sal
mo
nel
la
Var
iab
le
Dat
a so
urc
e D
istr
ibu
tio
n
Ou
tpu
t O
utp
ut
un
its
Co
mm
ents
2015
Pop
ulat
ion
AB
S
15
5256
7
Inci
denc
e K
irk e
t al
201
4 (1
0)
Ris
kOut
put 0
.008
, 0.
013,
0.0
23
2092
4 (9
0% C
rI 1
2059
-36
,50)
C
ases
S
tatis
tical
mod
el in
corp
orat
ing
NN
DS
S n
otifi
catio
n nu
mbe
rs fo
r 20
13 (
3003
), 2
014
(370
5), a
nd 2
015
(386
7) w
ith m
ultip
liers
for
unde
rrep
ortin
g an
d do
mes
tic
acqu
isiti
on,
No
med
ical
car
e
Ris
kOut
put 0
.31,
0.4
5,
0.6
9367
(95
% C
rI 4
484-
1810
8)
Cas
es
1 -
(%G
P v
isits
+ %
hosp
italis
ed +
%
ED
vis
its)
GP
vis
its
NG
SII
(11)
A
ltPer
t 0.2
5, 0
.37,
0.5
0 75
86 (
90%
CrI
395
7-14
364)
G
P v
isits
G
P v
isit
dist
ribut
ion
mul
tiplie
d by
in
cide
nce
outp
ut d
istr
ibut
ion
ED
vis
its
NG
SII
(11)
S
ame
met
hod
as
GP
AltP
ert 0
.06,
0.1
24,
0.22
8 25
60 (
90%
CrI
113
0-55
64)
ED
vis
its
ED
vis
it di
strib
utio
n m
ultip
lied
by
inci
denc
e ou
tput
dis
trib
utio
n
Hos
pita
lisat
ions
A
IHW
(2,
3)
Ris
kOut
put 0
.02,
0.0
5,
0.09
98
4 (9
0% C
rI 6
61-1
346)
Hos
pita
lisat
ions
Sta
tistic
al m
odel
inco
rpor
atin
g A
IHW
pr
imar
y di
agno
ses
for
2011
/12
(439
), 2
012/
13 (
426)
, 201
3/14
(49
3)
with
mul
tiplie
rs fo
r un
derr
epor
ting
and
dom
estic
acq
uisi
tion
Day
s in
hos
pita
l A
IHW
prim
ary
di
agno
sis
2013
-14
– A
LOS
(3)
2.
85
Day
s
AIH
W p
rovi
des
<1
year
, 1-4
yea
rs,
and
5 ye
ar a
ge g
roup
s af
ter
that
up
to 8
5+. A
wei
ghte
d av
erag
e A
LOS
is
calc
ulat
ed fo
r ou
r ag
e gr
oups
. D
eath
s A
ustr
alia
n B
urea
u of
Sta
tistic
s R
iskO
utpu
t 0.0
0002
, 0.
0000
3, 0
.000
06
0.65
(90
% C
rI 0
.5-0
.82)
D
eath
s S
tatis
tical
mod
el in
corp
orat
ing
AB
S
deat
hs w
ith m
ultip
liers
for
131
unde
rrep
ortin
g an
d do
mes
tic
acqu
isiti
on
Med
icat
ions
N
GS
II -
Adj
uste
d fo
r se
verit
y. 0
-4
age
grou
p on
ly
A
ntid
iarr
hoea
l
Per
t 0.0
025,
0.0
03, 0
.3
860
(90%
CrI
110
-325
0)M
edic
atio
ns
Med
icat
ion
dist
ribut
ions
mul
tiplie
d by
inci
denc
e ou
tput
dis
trib
utio
n
P
aink
iller
AltP
ert 0
.12,
0.3
8, 0
.65
7709
(90
% C
rI 2
738-
1664
5)
Med
icat
ions
A
nti-n
ause
a
Per
t 0.0
025,
0.0
03,
0.30
5 86
0 (9
0% C
rI 1
10-3
250)
Med
icat
ions
A
nti-c
ram
ps
0,
0, 0
0
Med
icat
ions
A
ntib
iotic
s
AltP
ert 0
.003
, 0.0
82,
0.30
5 16
64 (
90%
CrI
133
-63
28)
Med
icat
ions
Sto
ol c
ultu
re a
nd/o
r P
CR
N
ND
SS
S
alm
onel
la
notif
icat
ions
(5)
3003
, 370
5, 3
867
3705
S
tool
cul
ture
s N
ND
SS
Sal
mon
ella
not
ifica
tions
for
age
grou
p fo
r 20
13, 2
014,
and
201
5.
Out
put i
s m
edia
n of
yea
rs.
Day
s lo
st o
f pai
d w
ork
due
to b
eing
ill
NG
SII
- A
djus
ted
for
seve
rity.
0-4
on
ly (
11)
0, 0
, 0
0 D
ays
NG
SII
ques
tion
Q34
B. D
ays
lost
di
strib
utio
n m
ultip
lied
by in
cide
nce
outp
ut d
istr
ibut
ion
Day
s lo
st o
f pai
d w
ork
due
to c
arin
g N
GS
II -
Adj
uste
d fo
r se
verit
y. 0
-4
only
(11
)
AltP
ert 0
.692
, 1.3
, 2.2
2326
896
(90%
CrI
124
09-
5639
3)
Day
s N
GS
II qu
estio
n Q
35B
. D
ays
lost
di
strib
utio
n m
ultip
lied
by in
cide
nce
outp
ut d
istr
ibut
ion
Day
s lo
st o
f act
iviti
es
due
to b
eing
ill
NG
SII
- A
djus
ted
for
seve
rity.
0-4
on
ly (
11)
AltP
ert 1
.7, 2
.6, 3
.81
5398
4 (9
0% C
rI 2
7730
-10
3367
) D
ays
NG
SII
ques
tion
Q34
. Inc
lude
s pa
id
wor
k &
non
-pai
d ac
tiviti
es.
Day
s lo
st d
istr
ibut
ion
mul
tiplie
d by
in
cide
nce
outp
ut d
istr
ibut
ion
Day
s lo
st o
f ac
tiviti
es
due
to c
arin
g N
GS
II -
Adj
uste
d fo
r se
verit
y. 0
-4
only
(11
)
AltP
ert 2
.024
, 3, 4
.283
62
238
(90%
CrI
322
25-
1193
40)
Day
s N
GS
II qu
estio
n Q
35. I
nclu
des
paid
w
ork
& n
on-p
aid
activ
ities
. D
ays
lost
dis
trib
utio
n m
ultip
lied
by
inci
denc
e ou
tput
dis
trib
utio
n IB
S f
ollo
win
g S
alm
on
ella
132
Inci
denc
e F
ord
et a
l 201
4 (7
)
1.46
(90
% C
rI 0
.82-
2.57
) C
ases
A
ttrib
utab
le r
isk
of I
BS
app
lied
to t
he
estim
ated
Sal
mon
ella
inci
denc
e fo
r th
e ag
e gr
oup.
G
P v
isits
A
bels
on e
t al
20
06 (
1); F
lik e
t al
2015
(6)
AltP
ert 4
.27,
4.5
, 4.7
3 7
(90%
CrI
4-1
2)
GP
vis
its
GP
vis
it di
strib
utio
n m
ultip
lied
by
inci
denc
e ou
tput
dis
trib
utio
n
ED
vis
its
Abe
lson
et a
l 20
06 (
1)
0, 0
, 0
0 E
D v
isits
Hos
pita
lisat
ions
A
IHW
(2,
3)
Ris
kOut
put 0
.07,
0.1
9,
0.41
0.
29 (
90%
CrI
0-0
.53)
H
ospi
talis
atio
nsS
tatis
tical
mod
el in
corp
orat
ing
AIH
W
prim
ary
diag
nose
s fo
r 20
11/1
2 (0
),
2012
/13
(7),
201
3/14
(6)
with
m
ultip
liers
for
unde
rrep
ortin
g,
dom
estic
acq
uisi
tion,
and
pro
port
ion
due
to e
nter
ic in
fect
ion.
The
n 24
.3%
of
IB
S h
ospi
talis
atio
ns a
ttrib
uted
sp
ecifi
cally
to S
alm
onel
la.
Day
s in
hos
pita
l A
IHW
prim
ary
di
agno
sis
2013
-14
– A
LOS
(3)
4
Day
s A
IHW
pro
vide
s <
1 ye
ar, 1
-4 y
ears
, an
d 5
year
age
gro
ups
afte
r th
at u
p to
85+
. A w
eigh
ted
aver
age
ALO
S is
ca
lcul
ated
for
our
age
grou
ps.
Med
icat
ions
or
trea
tmen
ts
Exp
ert o
pini
on
AltP
ert 0
.385
, 0.4
, 0.4
160.
41 (
90%
CrI
0.2
2-0.
76)
Med
icat
ions
M
edic
atio
n di
strib
utio
n m
ultip
lied
by
inci
denc
e ou
tput
dis
trib
utio
n
Pat
holo
gy a
nd im
agin
g E
xper
t opi
nion
Tes
t dis
trib
utio
ns m
ultip
lied
by
inci
denc
e ou
tput
dis
trib
utio
n
Sto
ol c
ultu
re
P
ert 0
.667
, 1, 1
1.
38 (
90%
CrI
0.7
7-2.
45)
Tes
ts
F
BC
Per
t 0.6
67, 1
, 1
1.38
(90
% C
rI 0
.77-
2.45
) T
ests
E
SR
Per
t 0.6
67, 1
, 1
1.38
(90
% C
rI 0
.77-
2.45
) T
ests
LF
T
P
ert 0
.667
, 1, 1
1.
38 (
90%
CrI
0.7
7-2.
45)
Tes
ts
133
C
RP
Per
t 0.6
67, 1
, 1
1.38
(90
% C
rI 0
.77-
2.45
) T
ests
C
oelia
c di
seas
e
scre
enin
g
Per
t 0.6
67, 1
, 1
1.38
(90
% C
rI 0
.77-
2.45
) T
ests
R
adio
logy
AltP
ert 0
.652
, 0.6
67,
0.68
1 0.
97 (
90%
CrI
0.5
5-1.
71)
X-r
ays
U
ltras
ound
AltP
ert 0
.484
, 0.5
, 0.5
160.
73 (
90%
CrI
0.4
1-1.
28)
Ultr
asou
nds
E
ndos
copy
and
biop
sy
0,
0,
0 0
End
osco
pies
Spe
cial
ist
Exp
ert o
pini
on;
Can
avan
et
al
2014
(4)
AltP
ert 0
.286
, 0.3
, 0.3
150.
44 (
90%
CrI
0.2
5-0.
77)
Spe
cial
ist v
isits
S
peci
alis
t vis
it di
strib
utio
n m
ultip
lied
by in
cide
nce
outp
ut d
istr
ibut
ion
New
ong
oing
illn
ess
Mar
shal
l et a
l 20
07 (
13)
AltP
ert 0
.218
, 0.4
29,
0.66
2.
86 (
90%
CrI
1.3
5-5.
77)
Cas
es
New
ong
oing
illn
ess
dist
ribut
ion
mul
tiplie
d by
GP
vis
it ou
tput
+
hosp
italis
atio
n ou
tput
dis
trib
utio
ns
Day
s of
lost
pai
d w
ork
/ ac
tiviti
es
Abe
lson
et
al
2006
(1)
ass
umed
sa
me
as d
ays
in
hosp
ital +
tim
e vi
sitin
g G
P (
0.5
da
y)
4.
44 (
90%
CrI
2.8
1-7)
D
ays
(Hos
pita
lisat
ions
* A
LOS
) +
(G
P
visi
ts *
0.5
)
Lost
pai
d w
ork/
activ
ities
fr
om o
ngoi
ng il
lnes
s
9
(90%
CrI
4-1
7)
Day
s O
ngoi
ng il
lnes
s di
strib
utio
n m
ultip
lied
by lo
st p
rodu
ctiv
ity
(abo
ve)
ReA
fo
llow
ing
Sal
mo
nel
la
Inci
denc
e F
ord
et a
l 201
4 (7
)
341
(90%
CrI
56-
898)
C
ases
A
ttrib
utab
le r
isk
of R
eA a
pplie
d to
th
e es
timat
ed S
alm
onel
la in
cide
nce
for
the
age
grou
p. R
atio
of
0.09
3 ap
plie
d fo
r <
5s.
G
P v
isits
T
owne
s et
al 2
008
(14)
; A
bels
on e
t al
20
06 (
1)
AltP
ert 0
.66,
0.8
0, 0
.89
286
(90%
CrI
64-
720)
G
P v
isits
G
P v
isit
dist
ribut
ion
mul
tiplie
d by
in
cide
nce
outp
ut d
istr
ibut
ion
134
ED
vis
its
Abe
lson
et a
l 20
06 (
1)
0, 0
, 0
0 E
D v
isits
Hos
pita
lisat
ions
Ris
kOut
put 0
.002
, 0.0
1,
0.03
1.
84 (
90%
CrI
1.0
7-3.
52)
Hos
pita
lisat
ions
Sta
tistic
al m
odel
inco
rpor
atin
g A
IHW
pr
imar
y di
agno
ses
for
2011
/12
(10)
, 20
12/1
3 (6
), 2
013/
14 (
4) w
ith
mul
tiplie
rs fo
r un
derr
epor
ting,
do
mes
tic a
cqui
sitio
n an
d pr
opor
tion
due
to e
nter
ic in
fect
ion.
The
n 25
.3%
of
ReA
hos
pita
lisat
ions
att
ribut
ed
spec
ifica
lly to
Sal
mon
ella
. D
ays
in h
ospi
tal
AIH
W p
rima
ry
diag
nosi
s 20
13-1
4 –
ALO
S (
3)
2.
3 D
ays
AIH
W p
rovi
des
<1
year
, 1-4
yea
rs,
and
5 ye
ar a
ge g
roup
s af
ter
that
up
to 8
5+. A
wei
ghte
d av
erag
e A
LOS
is
calc
ulat
ed fo
r ou
r ag
e gr
oups
. M
edic
atio
ns o
r tr
eatm
ents
for
GP
vis
its
Med
icat
ion/
trea
tmen
t dis
trib
utio
ns
mul
tiplie
d by
GP
vis
it ou
tput
di
strib
utio
n
Ant
ibio
tics
Abe
lson
et a
l 20
06 (
1)
AltP
ert 0
.16,
0.2
, 0.2
44
53 (
90%
CrI
13-
146)
M
edic
atio
ns
N
SA
ID
Uot
ila e
t al
201
3 (1
5)
AltP
ert 0
.528
, 0.7
62,
0.91
8 19
9 (9
0% C
rI 4
6-55
1)
Med
icat
ions
E
ye d
rops
A
bels
on e
t al
2006
(1)
A
ltPer
t 0.1
6, 0
.2, 0
.244
53
(90
% C
rI 1
3-14
6)
Med
icat
ions
P
redn
ison
e A
bels
on e
t al
20
06 (
1)
Per
t 0.0
01, 0
.019
, 0.0
996
(90
% C
rI 1
-27)
M
edic
atio
ns
In
ter-
artic
ular
gl
ucoc
ortic
oid
Exp
ert o
pini
on
AltP
ert 0
.16,
0.2
, 0.2
44
53 (
90%
CrI
13-
146)
M
edic
atio
ns
D
MA
RD
U
otila
et
al 2
013
(15)
A
ltPer
t 0.0
12, 0
.095
, 0.
304
22 (
90%
CrI
3-1
15)
Med
icat
ions
Jo
int a
spira
tion
Exp
ert o
pini
on
AltP
ert 0
.16,
0.2
, 0.2
44
53 (
90%
CrI
13-
146)
T
reat
men
t
Pat
holo
gy a
nd im
agin
g fo
r G
P v
isits
T
ests
dis
trib
utio
ns m
ultip
lied
by G
P
visi
t ou
tput
dis
trib
utio
n
135
S
tool
cul
ture
E
xper
t opi
nion
A
ltPer
t 0.0
97, 0
.132
, 0.
174
35 (
90%
CrI
8-9
8)
Sto
ol c
ultu
res
S
erol
ogy
Exp
ert o
pini
on
AltP
ert 0
.097
, 0.1
32,
0.17
4 35
(90
% C
rI 8
-98)
S
erol
ogy
test
s
U
rine
m
icro
/cul
ture
/PC
R
Exp
ert o
pini
on
AltP
ert 0
.097
, 0.1
32,
0.17
4 35
(90
% C
rI 8
-98)
U
rine
cultu
res
C
RP
& U
rate
A
bels
on e
t al
2006
(1)
; Exp
ert
opin
ion
AltP
ert 0
.16,
0.2
, 0.2
44
53 (
90%
CrI
13-
146)
T
ests
F
BC
, ES
R
Abe
lson
et a
l 20
06 (
1); E
xper
t op
inio
n
AltP
ert 0
.16,
0.2
, 0.2
44
53 (
90%
CrI
13-
146)
T
ests
R
heum
atoi
d
fact
or
Abe
lson
et
al
2006
(1)
; Exp
ert
opin
ion
AltP
ert 0
.16,
0.2
, 0.2
44
53 (
90%
CrI
13-
146)
T
ests
R
enal
func
tion
Exp
ert o
pini
on
AltP
ert 0
.16,
0.2
, 0.2
44
53 (
90%
CrI
13-
146)
T
ests
B
lood
HLA
-B27
A
bels
on e
t al
2006
(1)
A
ltPer
t 0.1
6, 0
.2, 0
.244
53
(90
% C
rI 1
3-14
6)
Tes
ts
X
-ra
y E
xper
t opi
nion
A
ltPer
t 0.0
12, 0
.095
, 0.
304
22 (
90%
CrI
3-1
15)
X-r
ays
U
ltras
ound
E
xper
t opi
nion
A
ltPer
t 0.0
17, 0
.034
, 0.
062
9 (9
0% C
rI 2
-29)
U
ltras
ound
s
M
RI
Exp
ert o
pini
on
AltP
ert 0
.002
, 0.0
1, 0
.03
2 (9
0% C
rI 0
-11)
M
RIs
Spe
cial
ist v
isits
A
bels
on e
t al
2006
(1)
assu
med
da
ta a
nd b
ased
on
Han
nu e
t al
2002
(8)
Ref
erra
l to
a sp
ecia
list
20%
who
vis
it a
GP
are
ref
erre
d A
ltPer
t 0.1
6, 0
.2, 0
.244
53
(90
% C
rI 1
3-14
6)
Ref
erra
ls
Ref
erra
l dis
trib
utio
n m
ultip
lied
by G
P
visi
t ou
tput
dis
trib
utio
n
136
Spe
cial
ist v
isits
/yea
r 20
% o
f ref
erre
d ha
ve 2
vis
its p
er
year
AltP
ert 0
.223
, 0.2
4,
0.25
8 64
(90
% C
rI 1
5-17
2)
Spe
cial
ists
vi
sits
S
peci
alis
t dis
trib
utio
n m
ultip
lied
by
GP
vis
it ou
tput
dis
trib
utio
n
New
ong
oing
illn
ess
Leiri
salo
-Rep
o et
al
199
7 (1
2);
Han
nu e
t al 2
005
(9)
AltP
ert 0
.23,
0.5
, 0.7
7 89
(90
% C
rI 2
0-28
5)
Cas
es
New
ong
oing
illn
ess
dist
ribut
ion
mul
tiplie
d by
GP
vis
it ou
tput
+
hosp
italis
atio
n ou
tput
dis
trib
utio
ns
Day
s of
lost
act
iviti
es
Tow
nes
et a
l 200
8 (1
4)
AltP
ert 1
8.49
, 20.
15,
21.9
1 68
73 (
90%
CrI
162
2-18
130)
D
ays
“ReA
sym
ptom
s in
terf
ered
with
us
ual a
ctiv
ities
”. P
rodu
ctiv
ity
dist
ribut
ion
mul
tiplie
d by
inci
denc
e ou
tput
dis
trib
utio
n.
Day
s of
lost
pai
d w
ork
Tow
nes
et a
l 200
8 (1
4)
AltP
ert 2
.59,
3.3
7, 4
.3
1134
(90
% C
rI 2
67-
3117
) D
ays
“Mis
sed
wor
k be
caus
e of
ReA
sy
mpt
om
s”. P
rodu
ctiv
ity d
istr
ibut
ion
mul
tiplie
d by
inci
denc
e ou
tput
di
strib
utio
n.
Lost
pai
d w
ork
from
on
goin
g ill
ness
49
4 (9
5% C
I 195
-966
) D
ays
Ong
oing
illn
ess
dist
ribut
ion
mul
tiplie
d by
lost
pai
d w
ork
dist
ribut
ion
137
Age
gro
up: 5
-19
year
s
Sal
mo
nel
la
Var
iab
le
Dat
a so
urc
e D
istr
ibu
tio
n
Ou
tpu
t O
utp
ut
un
its
Co
mm
ents
Inci
denc
e K
irk e
t al
201
4 (1
0)
14
617
(90%
CrI
840
8-25
384)
C
ases
S
tatis
tical
mod
el in
corp
orat
ing
NN
DS
S
notif
icat
ion
num
bers
for
2013
(20
79),
20
14 (
2659
), a
nd 2
015
(266
4) w
ith
mul
tiplie
rs fo
r un
derr
epor
ting
and
dom
estic
acq
uisi
tion
No
med
ical
car
e
Ris
kOut
put 0
.31,
0.4
6,
0.59
66
44 (
90%
CrI
323
0-12
713)
C
ases
1
- (%
GP
vis
its +
%ho
spita
lised
+ %
ED
vi
sits
)
GP
vis
its
NG
SII
(11)
A
ltPer
t 0.2
5, 0
.37,
0.5
0 52
90 (
90%
CrI
281
3-99
47)
GP
vis
its
GP
vis
it di
strib
utio
n m
ultip
lied
by
inci
denc
e ou
tput
dis
trib
utio
n
ED
vis
its
NG
SII
(11)
S
ame
met
hod
as
GP
AltP
ert 0
.06,
0.1
24,
0.22
8 17
89 (
90%
CrI
792
-39
58)
ED
vis
its
ED
vis
it di
strib
utio
n m
ultip
lied
by
inci
denc
e ou
tput
dis
trib
utio
n
Hos
pita
lisat
ions
A
IHW
(2,
3)
Ris
kOut
put 0
.02,
0.0
4,
0.09
60
7 (9
0% C
rI 3
91-9
12)
Hos
pita
lisat
ions
Sta
tistic
al m
odel
inco
rpor
atin
g A
IHW
pr
imar
y di
agno
ses
for
2011
/12
(239
),
2012
/13
(271
), 2
013/
14 (
344)
with
m
ultip
liers
for
unde
rrep
ortin
g an
d do
mes
tic a
cqui
sitio
n D
ays
in h
ospi
tal
AIH
W p
rima
ry
diag
nosi
s 20
13-
14 –
ALO
S (
3)
3.
02 d
ays
Day
s
AIH
W p
rovi
des
<1
year
, 1-4
yea
rs, a
nd
5 ye
ar a
ge g
roup
s af
ter
that
up
to 8
5+.
A w
eigh
ted
aver
age
AL
OS
is c
alcu
late
d fo
r ou
r ag
e gr
oups
. D
eath
s A
ustr
alia
n B
urea
u of
Sta
tistic
s R
iskO
utpu
t 0.0
0006
, 0.
0001
2, 0
.000
21
1.7
(90%
CrI
1.3
4-2.
07)
Dea
ths
Sta
tistic
al m
odel
inco
rpor
atin
g A
BS
de
aths
with
mul
tiplie
rs fo
r un
derr
epor
ting
and
dom
estic
ac
quis
ition
M
edic
atio
ns
NG
SII
- A
djus
ted
for
seve
rity.
5-1
9
138
age
grou
p on
ly
(11)
A
ntid
iarr
hoea
l
Per
t 0.0
04, 0
.055
, 0.4
50
1420
(90
% C
rI 2
51-
4340
) M
edic
atio
ns
Med
icat
ion
dist
ribut
ions
mul
tiplie
d by
in
cide
nce
outp
ut d
istr
ibut
ion
P
aink
iller
AltP
ert 0
.042
, 0.1
94,
0.62
9 27
74 (
90%
CrI
656
-94
65)
Med
icat
ions
A
nti-n
ause
a
Per
t 0.0
04, 0
.055
, 0.4
50
1420
(90
% C
rI 2
51-
4340
) M
edic
atio
ns
A
nti-c
ram
ps
P
ert 0
.004
,0.0
45,0
.45
1310
(90
% C
rI 2
20-
4200
) M
edic
atio
ns
A
ntib
iotic
s
Per
t 0.0
04,0
.045
,0.4
5 13
10 (
90%
CrI
220
-42
00)
Med
icat
ions
Sto
ol c
ultu
re a
nd/o
r P
CR
N
ND
SS
S
alm
onel
la
notif
icat
ions
(5)
2079
, 265
9, 2
664
2659
S
tool
cul
ture
s N
ND
SS
Sal
mon
ella
not
ifica
tions
for
age
grou
p fo
r 20
13, 2
014,
and
201
5. O
utpu
t is
med
ian
of y
ears
. D
ays
lost
of p
aid
wor
k du
e to
bei
ng il
l N
GS
II -
Adj
uste
d fo
r se
verit
y. 5
-19
only
(11
)
AltP
ert 0
.04,
0.3
33, 1
.2
4778
(90
% C
rI 7
30-
1752
9)
Day
s N
GS
II qu
estio
n Q
34B
. Day
s lo
st
dist
ribut
ion
mul
tiplie
d by
inci
denc
e ou
tput
dis
trib
utio
n D
ays
lost
of p
aid
wor
k du
e to
car
ing
NG
SII
- A
djus
ted
for
seve
rity.
5-1
9 on
ly (
11)
AltP
ert 0
.103
,0.5
,1.4
61
7238
(90
% C
rI 1
668-
2168
8)
Day
s N
GS
II qu
estio
n Q
35B
. D
ays
lost
di
strib
utio
n m
ultip
lied
by in
cide
nce
outp
ut d
istr
ibut
ion
Day
s lo
st o
f act
iviti
es
due
to b
eing
ill
NG
SII
- A
djus
ted
for
seve
rity.
5-1
9 on
ly (
11)
AltP
ert 5
.18,
7.1
7, 9
.65
1041
21 (
90%
CrI
560
52-
1924
10)
Day
s N
GS
II qu
estio
n Q
34. I
nclu
des
paid
w
ork
& n
on-p
aid
activ
ities
. D
ays
lost
di
strib
utio
n m
ultip
lied
by in
cide
nce
outp
ut d
istr
ibut
ion
Day
s lo
st o
f act
iviti
es
due
to c
arin
g N
GS
II -
Adj
uste
d fo
r se
verit
y. 5
-19
only
(11
)
AltP
ert 0
.686
, 1.5
, 2.8
5 21
608
(90%
CrI
916
3-48
450)
D
ays
NG
SII
ques
tion
Q35
. Inc
lude
s pa
id
wor
k &
non
-pai
d ac
tiviti
es.
Day
s lo
st
dist
ribut
ion
mul
tiplie
d by
inci
denc
e ou
tput
dis
trib
utio
n IB
S f
ollo
win
g S
alm
on
ella
In
cide
nce
For
d et
al 2
014
(7)
12
84 (
90%
CrI
714
-23
08)
Cas
es
Att
ribut
able
ris
k of
IB
S a
pplie
d to
the
es
timat
ed S
alm
onel
la in
cide
nce
for
the
age
grou
p.
139
GP
vis
its
Abe
lson
et a
l 20
06 (
1); F
lik e
t al
201
5 (6
)
AltP
ert 4
.27,
4.5
, 4.7
3 57
66 (
90%
CrI
320
6-10
398)
G
P v
isits
G
P v
isit
dist
ribut
ion
mul
tiplie
d by
in
cide
nce
outp
ut d
istr
ibut
ion
ED
vis
its
Abe
lson
et a
l 20
06 (
1)
0, 0
, 0
0 E
D v
isits
Hos
pita
lisat
ions
A
IHW
(2,
3)
Ris
kOut
put 0
.006
, 0.0
13,
0.02
4 16
(90
% C
rI 9
-25)
H
ospi
talis
atio
nsS
tatis
tical
mod
el in
corp
orat
ing
AIH
W
prim
ary
diag
nose
s fo
r 20
11/1
2 (3
17),
20
12/1
3 (2
95),
201
3/14
(20
6) w
ith
mul
tiplie
rs fo
r un
derr
epor
ting,
dom
estic
ac
quis
ition
, and
pro
port
ion
due
to
ente
ric in
fect
ion.
The
n 24
.3%
of I
BS
ho
spita
lisat
ions
attr
ibut
ed s
peci
fical
ly to
S
alm
onel
la.
Day
s in
hos
pita
l A
IHW
prim
ary
di
agno
sis
2013
-14
– A
LOS
(3
)
1.
66
Day
s A
IHW
pro
vide
s <
1 ye
ar, 1
-4 y
ears
, and
5
year
age
gro
ups
afte
r th
at u
p to
85+
. A
wei
ghte
d av
erag
e A
LO
S is
cal
cula
ted
for
our
age
grou
ps.
Med
icat
ions
or
trea
tmen
ts
Exp
ert o
pini
on
AltP
ert 0
.385
, 0.4
, 0.4
16
514
(90%
CrI
285
-923
) M
edic
atio
ns
Med
icat
ion
dist
ribut
ion
mul
tiplie
d by
in
cide
nce
outp
ut d
istr
ibut
ion
Pat
holo
gy a
nd im
agin
g E
xper
t opi
nion
Tes
t dis
trib
utio
ns m
ultip
lied
by
inci
denc
e ou
tput
dis
trib
utio
n
S
tool
cul
ture
Per
t 0.6
67, 1
, 1
1206
(90
% C
rI 6
68-
2190
) T
ests
F
BC
Per
t 0.6
67, 1
, 1
1206
(90
% C
rI 6
68-
2190
) T
ests
E
SR
Per
t 0.6
67, 1
, 1
1206
(90
% C
rI 6
68-
2190
) T
ests
LF
T
P
ert 0
.667
, 1, 1
12
06 (
90%
CrI
668
-21
90)
Tes
ts
C
RP
Per
t 0.6
67, 1
, 1
1206
(90
% C
rI 6
68-
2190
) T
ests
140
C
oelia
c di
seas
e
scre
enin
g
Per
t 0.6
67, 1
, 1
1206
(90
% C
rI 6
68-
2190
) T
ests
R
adio
logy
AltP
ert 0
.652
, 0.6
67,
0.68
1 85
5 (9
0% C
rI 4
75-1
535)
X
-ra
ys
U
ltras
ound
AltP
ert 0
.484
, 0.5
, 0.5
16
642
(90%
CrI
358
-115
3)
Ultr
asou
nds
E
ndos
copy
and
biop
sy
A
ltPer
t 0.0
5, 0
.1, 0
.,15
124
(90%
CrI
57-
257)
E
ndos
copi
es
Spe
cial
ist
Exp
ert
opin
ion;
C
anav
an e
t al
20
14 (
4)
AltP
ert 0
.286
, 0.3
, 0.3
15
385
(90%
CrI
214
-692
) S
peci
alis
t vis
its
Spe
cial
ist v
isit
dist
ribut
ion
mul
tiplie
d by
in
cide
nce
outp
ut d
istr
ibut
ion
New
ong
oing
illn
ess
Mar
shal
l et a
l 20
07 (
13)
AltP
ert 0
.218
, 0.4
29,
0.66
24
10 (
90%
CrI
113
0-50
60)
Cas
es
New
ong
oing
illn
ess
dist
ribut
ion
mul
tiplie
d by
GP
vis
it ou
tput
+
hosp
italis
atio
n ou
tput
dis
trib
utio
ns
Day
s of
lost
pai
d w
ork
/ ac
tiviti
es
Abe
lson
et
al
2006
(1)
as
sum
ed s
ame
as d
ays
in
hosp
ital +
tim
e vi
sitin
g G
P (
0.5
da
y)
(Hos
pita
lisat
ions
*
ALO
S)
+ (
GP
vis
its *
0.5
)29
50 (
90%
CrI
166
7-52
63)
Day
s (H
ospi
talis
atio
ns *
ALO
S)
+ (
GP
vis
its *
0.
5)
Lost
pai
d w
ork/
activ
ities
fr
om o
ngoi
ng il
lnes
s
66
99 (
90%
CrI
377
2-11
191)
D
ays
Ong
oing
illn
ess
dist
ribut
ion
mul
tiplie
d by
lost
pro
duct
ivity
(ab
ove)
ReA
fo
llow
ing
Sal
mo
nel
la
Inci
denc
e F
ord
et a
l 201
4 (7
)
1206
(90
% C
rI 2
90-
3125
) C
ases
A
ttrib
utab
le r
isk
of R
eA a
pplie
d to
the
es
timat
ed S
alm
onel
la in
cide
nce
for
the
age
grou
p.
GP
vis
its
Tow
nes
et a
l 20
08 (
14);
A
bels
on e
t al
20
06 (
1)
AltP
ert 0
.66,
0.8
0, 0
.89
952
(90%
CrI
229
-248
3)
GP
vis
its
GP
vis
it di
strib
utio
n m
ultip
lied
by
inci
denc
e ou
tput
dis
trib
utio
n
ED
vis
its
Abe
lson
et a
l 20
06 (
1)
0, 0
, 0
0 E
D v
isits
141
Hos
pita
lisat
ions
A
IHW
(2,
3)
Ris
kOut
put 0
.001
, 0.0
03,
0.01
5 4.
01 (
90%
CrI
2.6
7-6.
32)
Hos
pita
lisat
ions
Sta
tistic
al m
odel
inco
rpor
atin
g A
IHW
pr
imar
y di
agno
ses
for
2011
/12
(18)
, 20
12/1
3 (1
3), 2
013/
14 (
10)
with
m
ultip
liers
for
unde
rrep
ortin
g, d
omes
tic
acqu
isiti
on, a
nd p
ropo
rtio
n du
e to
en
teric
infe
ctio
n. T
hen
25.3
% o
f ReA
ho
spita
lisat
ions
attr
ibut
ed s
peci
fical
ly to
S
alm
onel
la.
Day
s in
hos
pita
l A
IHW
prim
ary
di
agno
sis
2013
-14
– A
LOS
(3
)
2.
83
Day
s A
IHW
pro
vide
s <
1 ye
ar, 1
-4 y
ears
, and
5
year
age
gro
ups
afte
r th
at u
p to
85+
. A
wei
ghte
d av
erag
e A
LO
S is
cal
cula
ted
for
our
age
grou
ps.
Med
icat
ions
or
trea
tmen
ts fo
r G
P v
isits
M
edic
atio
n/tr
eatm
ent d
istr
ibut
ions
m
ultip
lied
by G
P v
isit
outp
ut d
istr
ibut
ion
A
ntib
iotic
s A
bels
on e
t al
2006
(1)
A
ltPer
t 0.1
6, 0
.2, 0
.244
18
9 (9
0% C
rI 4
5-50
7)
Med
icat
ions
N
SA
ID
Uot
ila e
t al
201
3 (1
5)
AltP
ert 0
.528
, 0.7
62,
0.91
8 70
3 (9
0% C
rI 1
66-1
900)
M
edic
atio
ns
E
ye d
rops
A
bels
on e
t al
2006
(1)
A
ltPer
t 0.1
6, 0
.2, 0
.244
18
9 (9
0% C
rI 4
5-50
7)
Med
icat
ions
P
redn
ison
e A
bels
on e
t al
20
06 (
1)
Per
t 0.0
01, 0
.019
, 0.0
99
23 (
90%
CrI
4-9
5)
Med
icat
ions
In
ter-
artic
ular
gl
ucoc
ortic
oid
Exp
ert o
pini
on
AltP
ert 0
.16,
0.2
, 0.2
44
189
(90%
CrI
45-
507)
M
edic
atio
ns
D
MA
RD
U
otila
et
al 2
013
(15)
A
ltPer
t 0.0
12, 0
.095
, 0.
304
81 (
90%
CrI
10-
384)
M
edic
atio
ns
Jo
int a
spira
tion
Exp
ert o
pini
on
AltP
ert 0
.16,
0.2
, 0.2
44
189
(90%
CrI
45-
507)
T
reat
men
t
Pat
holo
gy a
nd im
agin
g fo
r G
P v
isits
T
ests
dis
trib
utio
ns m
ultip
lied
by G
P v
isit
outp
ut d
istr
ibut
ion
S
tool
cul
ture
E
xper
t opi
nion
A
ltPer
t 0.0
97, 0
.132
, 0.
174
125
(90%
CrI
29-
336)
S
tool
cul
ture
s
142
S
erol
ogy
Exp
ert o
pini
on
AltP
ert 0
.097
, 0.1
32,
0.17
4 12
5 (9
0% C
rI 2
9-33
6)
Ser
olog
y te
sts
U
rine
m
icro
/cul
ture
/PC
R
Exp
ert o
pini
on
AltP
ert 0
.097
, 0.1
32,
0.17
4 12
5 (9
0% C
rI 2
9-33
6)
Urin
e cu
lture
s
C
RP
& U
rate
A
bels
on e
t al
2006
(1)
; Exp
ert
opin
ion
AltP
ert 0
.16,
0.2
, 0.2
44
189
(90%
CrI
45-
507)
T
ests
F
BC
, ES
R
Abe
lson
et a
l 20
06 (
1); E
xper
t op
inio
n
AltP
ert 0
.16,
0.2
, 0.2
44
189
(90%
CrI
45-
507)
T
ests
R
heum
atoi
d
fact
or
Abe
lson
et
al
2006
(1)
; Exp
ert
opin
ion
AltP
ert 0
.16,
0.2
, 0.2
44
189
(90%
CrI
45-
507)
T
ests
R
enal
func
tion
Exp
ert o
pini
on
AltP
ert 0
.16,
0.2
, 0.2
44
189
(90%
CrI
45-
507)
T
ests
B
lood
HLA
-B27
A
bels
on e
t al
2006
(1)
A
ltPer
t 0.1
6, 0
.2, 0
.244
18
9 (9
0% C
rI 4
5-50
7)
Tes
ts
X
-ra
y E
xper
t opi
nion
A
ltPer
t 0.0
12, 0
.095
, 0.
304
81 (
90%
CrI
10-
384)
X
-ra
ys
U
ltras
ound
E
xper
t opi
nion
A
ltPer
t 0.0
17, 0
.034
, 0.
062
31 (
90%
CrI
7-1
00)
Ultr
asou
nds
M
RI
Exp
ert o
pini
on
AltP
ert 0
.002
, 0.0
1, 0
.03
8 (9
0% C
rI 1
-40)
M
RIs
Spe
cial
ist v
isits
A
bels
on e
t al
2006
(1)
assu
med
da
ta a
nd b
ased
on
Han
nu e
t al
2002
(8)
Ref
erra
l to
a sp
ecia
list
20%
who
vis
it a
GP
are
ref
erre
d A
ltPer
t 0.1
6, 0
.2, 0
.244
18
9 (9
0% C
rI 4
5-50
7)
Ref
erra
ls
Ref
erra
l dis
trib
utio
n m
ultip
lied
by G
P
visi
t ou
tput
dis
trib
utio
n
143
Spe
cial
ist v
isits
/yea
r 20
% o
f ref
erre
d ha
ve 2
vis
its p
er
year
AltP
ert 0
.223
, 0.2
4,
0.25
8 22
8 (9
0% C
rI 5
5-59
5)
Spe
cial
ists
vi
sits
S
peci
alis
t dis
trib
utio
n m
ultip
lied
by G
P
visi
t ou
tput
dis
trib
utio
n
New
ong
oing
illn
ess
Leiri
salo
-Rep
o et
al
199
7 (1
2);
Han
nu e
t al 2
005
(9)
AltP
ert 0
.23,
0.5
, 0.7
7 45
0 (9
0% C
rI 1
03-1
365)
C
ases
N
ew o
ngoi
ng il
lnes
s di
strib
utio
n m
ultip
lied
by G
P v
isit
outp
ut +
ho
spita
lisat
ion
outp
ut d
istr
ibut
ions
Day
s of
lost
act
iviti
es
Tow
nes
et a
l 20
08 (
14)
AltP
ert 1
8.49
, 20.
15,
21.9
1 24
271
(90%
CrI
583
0-62
950)
D
ays
“ReA
sym
ptom
s in
terf
ered
with
usu
al
activ
ities
”. P
rodu
ctiv
ity d
istr
ibut
ion
mul
tiplie
d by
inci
denc
e ou
tput
di
strib
utio
n.
Day
s of
lost
pai
d w
ork
Tow
nes
et a
l 20
08 (
14)
AltP
ert 2
.59,
3.3
7, 4
.3
4029
(90
% C
rI 9
71-
1074
9)
Day
s “M
isse
d w
ork
beca
use
of R
eA
sym
pto
ms”
. Pro
duct
ivity
dis
trib
utio
n m
ultip
lied
by in
cide
nce
outp
ut
dist
ribut
ion.
Lo
st p
aid
wor
k fr
om
ongo
ing
illne
ss
1507
(95
% C
I 342
-473
6)D
ays
Ong
oing
illn
ess
dist
ribut
ion
mul
tiplie
d by
lost
pai
d w
ork
dist
ribut
ion
144
Age
gro
up: 2
0-64
yea
rs
Sal
mo
nel
la
Var
iab
le
Dat
a so
urc
e D
istr
ibu
tio
n
Ou
tpu
t O
utp
ut
un
its
Co
mm
ents
Inci
denc
e K
irk e
t al
201
4 (1
0)
44
525
(90%
CrI
250
12-
7748
9)
Cas
es
Sta
tistic
al m
odel
inco
rpor
atin
g N
ND
SS
not
ifica
tion
num
bers
for
2013
(6
083)
, 201
4 (8
027)
, and
201
5 (8
408)
w
ith m
ultip
liers
for
unde
rrep
ortin
g an
d do
mes
tic a
cqui
sitio
n
No
med
ical
car
e
Ris
kOut
put 0
.47,
0.5
9,
0.70
26
075
(90%
CrI
133
34-
4809
3)
Cas
es
1 -
(%G
P v
isits
+ %
hosp
italis
ed +
%
ED
vis
its)
GP
vis
its
NG
SII
(11)
A
ltPer
t 0.2
5, 0
.37,
0.5
0 16
145
(90%
CrI
823
6-30
686)
G
P v
isits
G
P v
isit
dist
ribut
ion
mul
tiplie
d by
in
cide
nce
outp
ut d
istr
ibut
ion
ED
vis
its
NG
SII
(11)
S
ame
met
hod
as G
P
AltP
ert 0
.06,
0.1
24,
0.22
8 54
56 (
90%
CrI
230
1-12
014)
E
D v
isits
E
D v
isit
dist
ribut
ion
mul
tiplie
d by
in
cide
nce
outp
ut d
istr
ibut
ion
Hos
pita
lisat
ions
A
IHW
(2,
3)
Ris
kOut
put 0
.02,
0.0
4,
0.08
18
14 (
90%
CrI
116
2-27
50)
Hos
pita
lisat
ions
Sta
tistic
al m
odel
inco
rpor
atin
g A
IHW
pr
imar
y di
agno
ses
for
2011
/12
(708
),
2012
/13
(814
), 2
013/
14 (
1041
) w
ith
mul
tiplie
rs fo
r un
derr
epor
ting
and
dom
estic
acq
uisi
tion
Day
s in
hos
pita
l A
IHW
prim
ary
di
agno
sis
2013
-14
– A
LOS
(3
)
3.
80 d
ays
Day
s
AIH
W p
rovi
des
<1
year
, 1-4
yea
rs,
and
5 ye
ar a
ge g
roup
s af
ter
that
up
to
85+
. A w
eigh
ted
aver
age
ALO
S is
ca
lcul
ated
for
our
age
grou
ps.
Dea
ths
Aus
tral
ian
Bur
eau
of
Sta
tistic
s
Ris
kOut
put 0
.000
04,
0.00
008,
0.0
0015
3.
53 (
90%
CrI
2.7
1-4.
38)
Dea
ths
Sta
tistic
al m
odel
inco
rpor
atin
g A
BS
de
aths
with
mul
tiplie
rs fo
r un
derr
epor
ting
and
dom
estic
ac
quis
ition
M
edic
atio
ns
NG
SII
- A
djus
ted
for
seve
rity.
20-
64
145
age
grou
p on
ly
(11)
A
ntid
iarr
hoea
l
AltP
ert 0
.166
, 0.2
86,
0.43
9 12
569
(90%
CrI
605
6-24
515)
M
edic
atio
ns
Med
icat
ion
dist
ribut
ions
mul
tiplie
d by
in
cide
nce
outp
ut d
istr
ibut
ion
P
aink
iller
AltP
ert 0
.127
, 0.2
42,
0.38
5 10
630
(90%
CrI
481
0-21
791)
M
edic
atio
ns
A
nti-n
ause
a
AltP
ert 0
.042
, 0.1
2,
0.23
7 51
84 (
90%
CrI
187
0-12
430)
M
edic
atio
ns
A
nti-c
ram
ps
P
ert 0
.028
, 0.0
77,
0.20
4 37
89 (
90%
CrI
153
1-83
39)
Med
icat
ions
A
ntib
iotic
s
AltP
ert 0
.016
, 0.0
67,
0.16
9 29
34 (
90%
CrI
782
-819
4)
Med
icat
ions
Sto
ol c
ultu
re a
nd/o
r P
CR
N
ND
SS
S
alm
onel
la
notif
icat
ions
(5)
6083
, 802
7, 8
408
8207
S
tool
cul
ture
s N
ND
SS
Sal
mon
ella
not
ifica
tions
for
age
grou
p fo
r 20
13, 2
014,
and
201
5.
Out
put i
s m
edia
n of
yea
rs.
Day
s lo
st o
f pai
d w
ork
due
to b
eing
ill
NG
SII
- A
djus
ted
for
seve
rity.
20-
64
only
(11
)
AltP
ert 0
.929
, 1.2
56,
1.66
1 55
790
(90%
CrI
295
24-
1022
69)
Day
s N
GS
II qu
estio
n Q
34B
. Day
s lo
st
dist
ribut
ion
mul
tiplie
d by
inci
denc
e ou
tput
dis
trib
utio
n
Day
s lo
st o
f pai
d w
ork
due
to c
arin
g N
GS
II -
Adj
uste
d fo
r se
verit
y. 2
0-64
on
ly (
11)
AltP
ert 0
.159
, 0.3
08,
0.53
7 13
366
(90%
CrI
606
7-29
351)
D
ays
NG
SII
ques
tion
Q35
B.
Day
s lo
st
dist
ribut
ion
mul
tiplie
d by
inci
denc
e ou
tput
dis
trib
utio
n
Day
s lo
st o
f act
iviti
es
due
to b
eing
ill
NG
SII
- A
djus
ted
for
seve
rity.
20-
64
only
(11
)
AltP
ert 3
.847
, 4.4
87,
5.20
3 19
9771
(90
% C
rI 1
0970
6-35
3563
) D
ays
NG
SII
ques
tion
Q34
. Inc
lude
s pa
id
wor
k &
non
-pai
d ac
tiviti
es.
Day
s lo
st
dist
ribut
ion
mul
tiplie
d by
inci
denc
e ou
tput
dis
trib
utio
n D
ays
lost
of a
ctiv
ities
du
e to
car
ing
NG
SII
- A
djus
ted
for
seve
rity.
20-
64
only
(11
)
AltP
ert 0
.498
, 0.7
44,
1.06
8
3286
8 (9
0% C
rI 1
6828
-62
858)
D
ays
NG
SII
ques
tion
Q35
. Inc
lude
s pa
id
wor
k &
non
-pai
d ac
tiviti
es.
Day
s lo
st
dist
ribut
ion
mul
tiplie
d by
inci
denc
e ou
tput
dis
trib
utio
n IB
S f
ollo
win
g S
alm
on
ella
146
Inci
denc
e F
ord
et a
l 201
4 (7
)
3906
(90
% C
rI 2
104-
7077
) C
ases
A
ttrib
utab
le r
isk
of IB
S a
pplie
d to
the
estim
ated
Sal
mon
ella
inci
denc
e fo
r th
e ag
e gr
oup.
G
P v
isits
A
bels
on e
t al
20
06 (
1); F
lik e
t al
201
5 (6
)
AltP
ert 4
.27,
4.5
, 4.7
3 17
582
(90%
CrI
947
1-31
969)
G
P v
isits
G
P v
isit
dist
ribut
ion
mul
tiplie
d by
in
cide
nce
outp
ut d
istr
ibut
ion
ED
vis
its
Abe
lson
et a
l 20
06 (
1)
0, 0
, 0
0 E
D v
isits
Hos
pita
lisat
ions
A
IHW
(2,
3)
Ris
kOut
put 0
.04,
0.0
8,
0.18
32
6 (9
0% C
rI 1
86-5
17)
Hos
pita
lisat
ions
Sta
tistic
al m
odel
inco
rpor
atin
g A
IHW
pr
imar
y di
agno
ses
for
2011
/12
(681
0),
2012
/13
(555
8), 2
013/
14 (
5027
) w
ith
mul
tiplie
rs fo
r un
derr
epor
ting,
do
mes
tic a
cqui
sitio
n, a
nd p
ropo
rtio
n du
e to
ent
eric
infe
ctio
n. T
hen
24.3
%
of I
BS
hos
pita
lisat
ions
attr
ibut
ed
spec
ifica
lly to
Sal
mon
ella
. D
ays
in h
ospi
tal
AIH
W p
rima
ry
diag
nosi
s 20
13-
14 –
ALO
S (
3)
1.
22
Day
s A
IHW
pro
vide
s <
1 ye
ar, 1
-4 y
ears
, an
d 5
year
age
gro
ups
afte
r th
at u
p to
85
+. A
wei
ghte
d av
erag
e A
LOS
is
calc
ulat
ed fo
r ou
r ag
e gr
oups
. M
edic
atio
ns o
r tr
eatm
ents
E
xper
t opi
nion
A
ltPer
t 0.3
85, 0
.4,
0.41
6 15
62 (
90%
CrI
840
-283
8)
Med
icat
ions
M
edic
atio
n di
strib
utio
n m
ultip
lied
by
inci
denc
e ou
tput
dis
trib
utio
n
Pat
holo
gy o
r im
agin
g E
xper
t opi
nion
Tes
t dis
trib
utio
ns m
ultip
lied
by
inci
denc
e ou
tput
dis
trib
utio
n
S
tool
cul
ture
Per
t 0.6
67, 1
, 1
3684
(90
% C
rI 1
984-
6696
) T
ests
F
BC
Per
t 0.6
67, 1
, 1
3684
(90
% C
rI 1
984-
6696
) T
ests
E
SR
Per
t 0.6
67, 1
, 1
3684
(90
% C
rI 1
984-
6696
) T
ests
LF
T
P
ert 0
.667
, 1, 1
36
84 (
90%
CrI
198
4-66
96)
Tes
ts
147
C
RP
Per
t 0.6
67, 1
, 1
3684
(90
% C
rI 1
984-
6696
) T
ests
C
oelia
c di
seas
e
scre
enin
g
Per
t 0.6
67, 1
, 1
3684
(90
% C
rI 1
984-
6696
) T
ests
R
adio
logy
AltP
ert 0
.652
, 0.6
67,
0.68
1 26
06 (
90%
CrI
140
5-47
17)
X-r
ays
U
ltras
ound
AltP
ert 0
.484
, 0.5
, 0.
516
1951
(90
% C
rI 1
051-
3542
) U
ltras
ound
s
E
ndos
copy
and
biop
sy
A
ltPer
t 0.0
5, 0
.1, 0
.,15
379
(90%
CrI
168
-798
) E
ndos
copi
es
Spe
cial
ist
Exp
ert o
pini
on;
Can
avan
et
al
2014
(4)
AltP
ert 0
.286
, 0.3
, 0.
315
1171
(90
% C
rI 6
32-2
120)
S
peci
alis
t vis
its
Spe
cial
ist v
isit
dist
ribut
ion
mul
tiplie
d by
inci
denc
e ou
tput
dis
trib
utio
n
New
ong
oing
illn
ess
Mar
shal
l et a
l 20
07 (
13)
AltP
ert 0
.218
, 0.4
29,
0.66
74
74 (
90%
CrI
337
0-15
720)
C
ases
N
ew o
ngoi
ng il
lnes
s di
strib
utio
n m
ultip
lied
by G
P v
isit
outp
ut +
ho
spita
lisat
ion
outp
ut d
istr
ibut
ions
D
ays
of lo
st p
aid
wor
k /
activ
ities
A
bels
on e
t al
20
06 (
1)
assu
med
sam
e as
day
s in
ho
spita
l + ti
me
visi
ting
GP
(0.
5 d
ay)
(Hos
pita
lisat
ions
*
ALO
S)
+ (
GP
vis
its *
0.
5)
1012
5 (9
0% C
rI 6
002-
1732
1)
Day
s (H
ospi
talis
atio
ns *
ALO
S)
+ (
GP
vis
its
* 0.
5)
Lost
pai
d w
ork/
activ
ities
fr
om o
ngoi
ng il
lnes
s
17
705
(90%
CrI
796
8-34
322)
D
ays
Ong
oing
illn
ess
dist
ribut
ion
mul
tiplie
d by
lost
pro
duct
ivity
(ab
ove)
ReA
fo
llow
ing
Sal
mo
nel
la
Inci
denc
e F
ord
et a
l 201
4 (7
)
2883
(90
% C
rI 6
88-7
718)
C
ases
A
ttrib
utab
le r
isk
of R
eA a
pplie
d to
the
estim
ated
Sal
mon
ella
inci
denc
e fo
r th
e ag
e gr
oup.
G
P v
isits
T
owne
s et
al
2008
(14
);
Abe
lson
et
al
2006
(1)
AltP
ert 0
.66,
0.8
, 0.8
9 28
83 (
90%
CrI
688
-771
8)
GP
vis
its
GP
vis
it di
strib
utio
n m
ultip
lied
by
inci
denc
e ou
tput
dis
trib
utio
n
148
ED
vis
its
Abe
lson
et a
l 20
06 (
1)
0, 0
, 0
0 E
D v
isits
Hos
pita
lisat
ions
A
IHW
(2,
3)
Ris
kOut
put 0
.002
, 0.
005,
0.0
23
20 (
90%
CrI
13-
26)
Hos
pita
lisat
ions
Sta
tistic
al m
odel
inco
rpor
atin
g A
IHW
pr
imar
y di
agno
ses
for
2011
/12
(71)
, 20
12/1
3 (7
1), 2
013/
14 (
50)
with
m
ultip
liers
for
unde
rrep
ortin
g,
dom
estic
acq
uisi
tion,
and
pro
port
ion
due
to e
nter
ic in
fect
ion.
The
n 25
.3%
of
ReA
hos
pita
lisat
ions
att
ribut
ed
spec
ifica
lly to
Sal
mon
ella
. D
ays
in h
ospi
tal
AIH
W p
rima
ry
diag
nosi
s 20
13-
14 –
ALO
S (
3)
3.
56
Day
s A
IHW
pro
vide
s <
1 ye
ar, 1
-4 y
ears
, an
d 5
year
age
gro
ups
afte
r th
at u
p to
85
+. A
wei
ghte
d av
erag
e A
LOS
is
calc
ulat
ed fo
r ou
r ag
e gr
oups
. M
edic
atio
ns o
r tr
eatm
ents
for
thos
e w
ho
visi
t a G
P
Med
icat
ion/
trea
tmen
t dis
trib
utio
ns
mul
tiplie
d by
GP
vis
it ou
tput
di
strib
utio
n
Ant
ibio
tics
Abe
lson
et a
l 20
06 (
1)
AltP
ert 0
.16,
0.2
, 0.2
44
576
(90%
CrI
133
-155
1)
Med
icat
ions
N
SA
ID
Uot
ila e
t al
201
3 (1
5)
AltP
ert 0
.528
, 0.7
62,
0.91
8 21
31 (
90%
CrI
500
-589
7)
Med
icat
ions
E
ye d
rops
A
bels
on e
t al
2006
(1)
A
ltPer
t 0.1
6, 0
.2, 0
.244
57
6 (9
0% C
rI 1
33-1
551)
M
edic
atio
ns
P
redn
ison
e A
bels
on e
t al
20
06 (
1)
Per
t 0.0
01, 0
.019
, 0.
099
69 (
90%
CrI
10-
294)
M
edic
atio
ns
In
ter-
artic
ular
gl
ucoc
ortic
oid
Exp
ert o
pini
on
AltP
ert 0
.16,
0.2
, 0.2
44
576
(90%
CrI
133
-155
1)
Med
icat
ions
D
MA
RD
U
otila
et
al 2
013
(15)
A
ltPer
t 0.0
12, 0
.095
, 0.
304
240
(90%
CrI
30-
1213
) M
edic
atio
ns
Jo
int a
spira
tion
Exp
ert o
pini
on
AltP
ert 0
.16,
0.2
, 0.2
44
576
(90%
CrI
133
-155
1)
Tre
atm
ent
149
Pat
holo
gy a
nd im
agin
g fo
r th
ose
who
vis
it a
GP
T
ests
dis
trib
utio
ns m
ultip
lied
by G
P
visi
t ou
tput
dis
trib
utio
n
S
tool
cul
ture
E
xper
t opi
nion
A
ltPer
t 0.0
97, 0
.132
, 0.
174
378
(90%
CrI
88-
1044
) S
tool
cul
ture
s
S
erol
ogy
Exp
ert o
pini
on
AltP
ert 0
.097
, 0.1
32,
0.17
4 37
8 (9
0% C
rI 8
8-10
44
Ser
olog
y te
sts
U
rine
m
icro
/cul
ture
/PC
R
Exp
ert o
pini
on
AltP
ert 0
.097
, 0.1
32,
0.17
4 37
8 (9
0% C
rI 8
8-10
44
Urin
e cu
lture
s
C
RP
& U
rate
A
bels
on e
t al
2006
(1)
; Exp
ert
opin
ion
AltP
ert 0
.16,
0.2
, 0.2
44
576
(90%
CrI
133
-155
1)
Tes
ts
F
BC
, ES
R
Abe
lson
et a
l 20
06 (
1); E
xper
t op
inio
n
AltP
ert 0
.16,
0.2
, 0.2
44
576
(90%
CrI
133
-155
1)
Tes
ts
R
heum
atoi
d
fact
or
Abe
lson
et
al
2006
(1)
; Exp
ert
opin
ion
AltP
ert 0
.16,
0.2
, 0.2
44
576
(90%
CrI
133
-155
1)
Tes
ts
R
enal
func
tion
Exp
ert o
pini
on
AltP
ert 0
.16,
0.2
, 0.2
44
576
(90%
CrI
133
-155
1)
Tes
ts
B
lood
HLA
-B27
A
bels
on e
t al
2006
(1)
A
ltPer
t 0.1
6, 0
.2, 0
.244
57
6 (9
0% C
rI 1
33-1
551)
T
ests
X
-ra
y E
xper
t opi
nion
A
ltPer
t 0.0
12, 0
.095
, 0.
304
240
(90%
CrI
30-
1213
) X
-ra
ys
U
ltras
ound
E
xper
t opi
nion
A
ltPer
t 0.0
17, 0
.034
, 0.
062
94 (
90%
CrI
21-
308)
U
ltras
ound
s
M
RI
Exp
ert o
pini
on
AltP
ert 0
.002
, 0.0
1,
0.03
26
(90
% C
rI 4
-121
) M
RIs
Spe
cial
ist v
isits
A
bels
on e
t al
2006
(1
)ass
umed
da
ta a
nd b
ased
150
on H
annu
et a
l 20
02 (
8)
Ref
erra
l to
rheu
mat
olog
ist
20%
who
vis
it a
GP
are
ref
erre
d A
ltPer
t 0.1
6, 0
.2, 0
.244
57
6 (9
0% C
rI 1
33-1
551)
R
efer
rals
R
efer
ral d
istr
ibut
ion
mul
tiplie
d by
GP
vi
sit
outp
ut d
istr
ibut
ion
Spe
cial
ist v
isits
/yea
r 20
% o
f ref
erre
d ha
ve 2
vis
its p
er
year
AltP
ert 0
.223
, 0.2
4,
0.25
8 69
2 (9
0% C
rI 1
65-1
847)
S
peci
alis
ts
visi
ts
Spe
cial
ist d
istr
ibut
ion
mul
tiplie
d by
GP
vi
sit
outp
ut d
istr
ibut
ion
New
ong
oing
illn
ess
Leiri
salo
-Rep
o et
al 1
997
(12)
; H
annu
et a
l 20
05 (
9)
AltP
ert 0
.23,
0.5
, 0.7
7 13
73 (
90%
CrI
309
-418
5)
Cas
es
New
ong
oing
illn
ess
dist
ribut
ion
mul
tiplie
d by
GP
vis
it ou
tput
+
hosp
italis
atio
n ou
tput
dis
trib
utio
ns
Day
s of
lost
pai
d ac
tiviti
es
Tow
nes
et a
l 20
08 (
14)
AltP
ert 1
8.49
, 20.
15,
21.9
1 73
538
(90%
CrI
173
00-
1952
52)
Day
s “R
eA s
ympt
oms
inte
rfer
ed w
ith u
sual
ac
tiviti
es”.
Pro
duct
ivity
dis
trib
utio
n m
ultip
lied
by in
cide
nce
outp
ut
dist
ribut
ion.
D
ays
of lo
st p
aid
wor
k T
owne
s et
al
2008
(14
) A
ltPer
t 2.5
9, 3
.37,
4.3
12
231
(90%
CrI
286
8-33
333)
D
ays
“Mis
sed
wor
k be
caus
e of
ReA
sy
mpt
om
s”. P
rodu
ctiv
ity d
istr
ibut
ion
mul
tiplie
d by
inci
denc
e ou
tput
di
strib
utio
n.
Lost
pai
d w
ork
from
on
goin
g ill
ness
53
13 (
95%
CI 2
100-
1039
0)
Day
s O
ngoi
ng il
lnes
s di
strib
utio
n m
ultip
lied
by lo
st p
aid
wor
k di
strib
utio
n
151
Age
gro
up: 6
5+ y
ears
Var
iab
le
Dat
a so
urc
e D
istr
ibu
tio
n
Ou
tpu
t O
utp
ut
un
its
Co
mm
ents
Inci
denc
e K
irk e
t al
20
14 (
10)
10
767
(90%
CrI
610
4-19
042)
C
ases
S
tatis
tical
mod
el in
corp
orat
ing
NN
DS
S
notif
icat
ion
num
bers
for
2013
(15
24),
20
14 (
1867
), a
nd 2
015
(207
7) w
ith
mul
tiplie
rs fo
r un
derr
epor
ting
and
dom
estic
acq
uisi
tion
N
o m
edic
al c
are
R
iskO
utpu
t 0.4
0, 0
.54,
0.
66
5829
(90
% C
rI 2
754-
1132
6)
1
- (%
GP
vis
its +
%ho
spita
lised
+ %
ED
vi
sits
)
GP
vis
its
NG
SII
(11)
A
ltPer
t 0.2
5, 0
.37,
0.5
0 39
14 (
90%
CI 2
041-
7438
) G
P v
isits
G
P v
isit
dist
ribut
ion
mul
tiplie
d by
in
cide
nce
outp
ut d
istr
ibut
ion
ED
vis
its
NG
SII
(11)
S
ame
met
hod
as
GP
AltP
ert 0
.06,
0.1
24,
0.22
8 13
20 (
90%
CrI
568
-29
05)
ED
vis
its
ED
vis
it di
strib
utio
n m
ultip
lied
by
inci
denc
e ou
tput
dis
trib
utio
n
Hos
pita
lisat
ions
A
IHW
(2,
3)
Ris
kOut
put 0
.04,
0.0
8,
0.19
90
7 (9
0% C
I 570
-138
2)
Hos
pita
lisat
ions
Sta
tistic
al m
odel
inco
rpor
atin
g A
IHW
pr
imar
y di
agno
ses
for
2011
/12
(341
),
2012
/13
(419
), 2
013/
14 (
519)
with
m
ultip
liers
for
unde
rrep
ortin
g an
d do
mes
tic a
cqui
sitio
n D
ays
in h
ospi
tal
AIH
W
prim
ary
diag
nosi
s 20
13-1
4 –
ALO
S (
3)
6.
80 d
ays
Day
s
AIH
W p
rovi
des
<1
year
, 1-4
yea
rs, a
nd 5
ye
ar a
ge g
roup
s af
ter
that
up
to 8
5+. A
w
eigh
ted
aver
age
ALO
S is
cal
cula
ted
for
our
age
grou
ps.
Dea
ths
Aus
tral
ian
Bur
eau
of
Sta
tistic
s
Ris
kOut
put 0
.000
6,
0.00
12, 0
.002
1 13
(90
% C
I 10-
15)
Dea
ths
Sta
tistic
al m
odel
inco
rpor
atin
g A
BS
de
aths
with
mul
tiplie
rs fo
r un
derr
epor
ting
and
dom
estic
acq
uisi
tion
Med
icat
ions
N
GS
II -
Adj
uste
d fo
r se
verit
y. 6
5+
152
age
grou
p on
ly (
11)
A
ntid
iarr
hoea
l
AltP
ert 0
.094
, 0.6
53,
0.90
6
6573
(90
% C
rI 1
799-
1335
7)
Med
icat
ions
M
edic
atio
n di
strib
utio
ns m
ultip
lied
by
inci
denc
e ou
tput
dis
trib
utio
n
P
aink
iller
AltP
ert 0
.008
, 0.3
07,
0.70
8 31
62 (
90%
CrI
381
-85
59)
Med
icat
ions
A
nti-n
ause
a
AltP
ert 0
.008
, 0.3
07,
0.70
8 31
62 (
90%
CrI
381
-85
59)
Med
icat
ions
A
nti-c
ram
ps
A
ltPer
t 0.0
08, 0
.277
, 0.
708
2874
(90
% C
rI 3
18-
8416
) M
edic
atio
ns
A
ntib
iotic
s
0, 0
.051
, 0.1
04
531
(90%
CrI
59-
1309
) M
edic
atio
ns
Sto
ol c
ultu
re a
nd/o
r P
CR
N
ND
SS
S
alm
onel
la
notif
icat
ions
(5
)
1524
, 186
7, 2
077
1867
S
tool
cul
ture
s N
ND
SS
Sal
mon
ella
not
ifica
tions
for
age
grou
p fo
r 20
13, 2
014,
and
201
5. O
utpu
t is
med
ian
of y
ears
.
Day
s lo
st o
f pai
d w
ork
due
to b
eing
ill
NG
SII
- A
djus
ted
for
seve
rity.
65+
on
ly (
11)
AltP
ert 0
.081
, 0.6
67,
2.40
8 70
79 (
90%
CrI
109
0-25
866)
D
ays
NG
SII
ques
tion
Q34
B. D
ays
lost
di
strib
utio
n m
ultip
lied
by in
cide
nce
outp
ut
dist
ribut
ion
Day
s lo
st o
f pai
d w
ork
due
to b
eing
car
ed f
or
NG
SII
- A
djus
ted
for
seve
rity.
65+
on
ly (
11)
Per
t 0.0
08, 0
.33,
1.8
57
5084
(90
% C
rI 1
006-
1463
2)
Day
s N
GS
II qu
estio
n Q
35B
. D
ays
lost
di
strib
utio
n m
ultip
lied
by in
cide
nce
outp
ut
dist
ribut
ion
Day
s lo
st o
f act
iviti
es
due
to b
eing
ill
NG
SII
- A
djus
ted
for
seve
rity.
65+
on
ly (
11)
AltP
ert 4
.86,
7.6
67,
11.5
04
8215
8 (9
0% C
rI 4
1194
-16
1843
) D
ays
NG
SII
ques
tion
Q34
. Inc
lude
s pa
id w
ork
&
non-
paid
act
iviti
es.
Day
s lo
st d
istr
ibut
ion
mul
tiplie
d by
inci
denc
e ou
tput
dis
trib
utio
n
Day
s lo
st o
f act
iviti
es
due
to c
arin
g N
GS
II -
Adj
uste
d fo
r se
verit
y. 6
5+
only
(11
)
Per
t 0.0
08, 0
.33,
1.8
57
5071
(90
% C
rI 9
98-
1458
7)
Day
s N
GS
II qu
estio
n Q
35. I
nclu
des
paid
wor
k &
no
n-pa
id a
ctiv
ities
. D
ays
lost
dis
trib
utio
n m
ultip
lied
by in
cide
nce
outp
ut d
istr
ibut
ion
IBS
fo
llow
ing
Sal
mo
nel
la
153
Inci
denc
e F
ord
et a
l 20
14 (
7)
94
2 (9
0% C
rI 5
16-1
703)
C
ases
A
ttrib
utab
le r
isk
of IB
S a
pplie
d to
the
estim
ated
Sal
mon
ella
inci
denc
e fo
r th
e ag
e gr
oup.
G
P v
isits
A
bels
on e
t al
20
06 (
1); F
lik
et a
l 201
5 (6
)
AltP
ert 4
.27,
4.5
, 4.7
3 42
29 (
90%
CrI
231
6-76
55)
GP
vis
its
GP
vis
it di
strib
utio
n m
ultip
lied
by
inci
denc
e ou
tput
dis
trib
utio
n
ED
vis
its
Abe
lson
et a
l 20
06 (
1)
0, 0
, 0
0 E
D v
isits
Hos
pita
lisat
ions
A
IHW
(2,
3)
Ris
kOut
put 0
.03,
0.0
7,
0.16
67
(90
% C
rI 3
9-10
4)
Hos
pita
lisat
ions
Sta
tistic
al m
odel
inco
rpor
atin
g A
IHW
pr
imar
y di
agno
ses
for
2011
/12
(136
8),
2012
/13
(113
1), 2
013/
14 (
1086
) w
ith
mul
tiplie
rs fo
r un
derr
epor
ting,
dom
estic
ac
quis
ition
, and
pro
port
ion
due
to e
nter
ic
infe
ctio
n. T
hen
24.3
% o
f IB
S
hosp
italis
atio
ns a
ttrib
uted
spe
cific
ally
to
Sal
mon
ella
. D
ays
in h
ospi
tal
AIH
W
prim
ary
diag
nosi
s 20
13-1
4 –
ALO
S (
3)
1.
2 D
ays
AIH
W p
rovi
des
<1
year
, 1-4
yea
rs, a
nd 5
ye
ar a
ge g
roup
s af
ter
that
up
to 8
5+. A
w
eigh
ted
aver
age
ALO
S is
cal
cula
ted
for
our
age
grou
ps.
Med
icat
ions
or
trea
tmen
ts
Exp
ert
opin
ion
AltP
ert 0
.385
, 0.4
, 0.4
16
377
(90%
CrI
207
-684
) M
edic
atio
ns
Med
icat
ion
dist
ribut
ion
mul
tiplie
d by
in
cide
nce
outp
ut d
istr
ibut
ion
Pat
holo
gy o
r im
agin
g E
xper
t op
inio
n
Tes
t dis
trib
utio
ns m
ultip
lied
by in
cide
nce
outp
ut d
istr
ibut
ion
S
tool
cul
ture
Per
t 0.6
67, 1
, 1
889
(90%
CrI
485
-161
0)
Tes
ts
F
BC
Per
t 0.6
67, 1
, 1
889
(90%
CrI
485
-161
0)
Tes
ts
E
SR
Per
t 0.6
67, 1
, 1
889
(90%
CrI
485
-161
0)
Tes
ts
LF
T
P
ert 0
.667
, 1, 1
88
9 (9
0% C
rI 4
85-1
610)
T
ests
154
C
RP
Per
t 0.6
67, 1
, 1
889
(90%
CrI
485
-161
0)
Tes
ts
C
oelia
c di
seas
e
scre
enin
g
Per
t 0.6
67, 1
, 1
889
(90%
CrI
485
-161
0)
Tes
ts
R
adio
logy
AltP
ert 0
.652
, 0.6
67,
0.68
1 62
9 (9
0% C
rI 3
44-1
134)
X
-ra
ys
U
ltras
ound
AltP
ert 0
.484
, 0.5
, 0.5
16
472
(90%
CrI
258
-849
) U
ltras
ound
s
E
ndos
copy
and
biop
sy
A
ltPer
t 0.1
5, 0
.2, 0
.25
186
(90%
CrI
99-
353)
E
ndos
copi
es
Spe
cial
ist
Exp
ert
opin
ion;
C
anav
an e
t al
201
4 (4
)
AltP
ert 0
.286
, 0.3
, 0.3
15
282
(90%
CrI
155
-512
) S
peci
alis
t vis
its
Spe
cial
ist v
isit
dist
ribut
ion
mul
tiplie
d by
in
cide
nce
outp
ut d
istr
ibut
ion
New
ong
oing
illn
ess
Mar
shal
l et a
l 20
07 (
13)
AltP
ert 0
.218
, 0.4
29,
0.66
17
92 (
90%
CrI
816
-37
56)
Cas
es
New
ong
oing
illn
ess
dist
ribut
ion
mul
tiplie
d by
GP
vis
it ou
tput
+ h
ospi
talis
atio
n ou
tput
di
strib
utio
ns
Day
s of
lost
pai
d w
ork
/ ac
tiviti
es
Abe
lson
et
al
2006
(1)
as
sum
ed
sam
e as
da
ys in
ho
spita
l +
time
visi
ting
GP
(0.
5 da
y)
(Hos
pita
lisat
ions
*
ALO
S)
+ (
GP
vis
its *
0.5
)23
94 (
90%
CrI
142
5-41
15)
Day
s (H
ospi
talis
atio
ns *
ALO
S)
+ (
GP
vis
its *
0.
5)
Lost
pai
d w
ork/
activ
ities
fr
om o
ngoi
ng il
lnes
s
42
03 (
90%
CrI
190
2-81
08)
Day
s O
ngoi
ng il
lnes
s di
strib
utio
n m
ultip
lied
by
lost
pro
duct
ivity
(ab
ove
) R
eA f
ollo
win
g S
alm
on
ella
In
cide
nce
For
d et
al
2014
(7)
881
(90%
CrI
209
-231
0)
Cas
es
Att
ribut
able
ris
k of
ReA
app
lied
to th
e es
timat
ed S
alm
onel
la in
cide
nce
for
the
age
grou
p.
GP
vis
its
Tow
nes
et a
l 20
08 (
14);
A
ltPer
t 0.6
6, 0
.80,
0.8
9 69
9 (9
0% C
I 165
-184
3)
GP
vis
its
GP
vis
it di
strib
utio
n m
ultip
lied
by
inci
denc
e ou
tput
dis
trib
utio
n
155
Abe
lson
et
al
2006
(1)
E
D v
isits
A
bels
on e
t al
2006
(1)
0,
0, 0
0
ED
vis
its
Hos
pita
lisat
ions
A
IHW
(2,
3)
Ris
kOut
pu 0
.001
, 0.0
03,
0.01
3 2.
54 (
90%
CI 1
.87-
3.88
) H
ospi
talis
atio
nsS
tatis
tical
mod
el in
corp
orat
ing
AIH
W
prim
ary
diag
nose
s fo
r 20
11/1
2 (8
),
2012
/13
(7),
201
3/14
(11
) w
ith m
ultip
liers
fo
r un
derr
epor
ting,
dom
estic
acq
uisi
tion,
an
d pr
opor
tion
due
to e
nter
ic in
fect
ion.
T
hen
25.3
% o
f R
eA h
ospi
talis
atio
ns
attr
ibut
ed s
peci
fical
ly t
o S
alm
onel
la.
Day
s in
hos
pita
l A
IHW
pr
imar
y di
agno
sis
2013
-14
– A
LOS
(3)
4.
2 D
ays
AIH
W p
rovi
des
<1
year
, 1-4
yea
rs, a
nd 5
ye
ar a
ge g
roup
s af
ter
that
up
to 8
5+. A
w
eigh
ted
aver
age
ALO
S is
cal
cula
ted
for
our
age
grou
ps.
Med
icat
ions
or
trea
tmen
ts fo
r th
ose
who
vi
sit a
GP
Med
icat
ion/
trea
tmen
t di
strib
utio
ns
mul
tiplie
d by
GP
vis
it ou
tput
dis
trib
utio
n
A
ntib
iotic
s A
bels
on e
t al
2006
(1)
A
ltPer
t 0.1
6, 0
.2, 0
.244
13
8 (9
0% C
rI 3
2-37
5)
Med
icat
ions
N
SA
ID
Uot
ila e
t al
20
13 (
15)
A
ltPer
t 0.5
28, 0
.762
, 0.
918
520
(90%
CrI
119
-140
3)
Med
icat
ions
E
ye d
rops
A
bels
on e
t al
2006
(1)
A
ltPer
t 0.1
6, 0
.2, 0
.244
13
8 (9
0% C
rI 3
2-37
5)
Med
icat
ions
P
redn
ison
e A
bels
on e
t al
20
06 (
1)
Per
t 0.0
01, 0
.019
, 0.0
99
17 (
90%
CrI
3-6
8)
Med
icat
ions
In
ter-
artic
ular
gl
ucoc
ortic
oid
Exp
ert
opin
ion
A
ltPer
t 0.1
6, 0
.2, 0
.244
13
8 (9
0% C
rI 3
2-37
5)
Med
icat
ions
D
MA
RD
U
otila
et a
l 20
13 (
15)
AltP
ert 0
.012
, 0.0
95,
0.30
4 59
(90
% C
rI 7
-281
) M
edic
atio
ns
Jo
int a
spira
tion
Exp
ert
opin
ion
AltP
ert 0
.16,
0.2
, 0.2
44
138
(90%
CrI
32-
375)
T
reat
men
t
156
Pat
holo
gy a
nd im
agin
g fo
r th
ose
who
vis
it a
GP
T
ests
dis
trib
utio
ns m
ultip
lied
by G
P v
isit
outp
ut d
istr
ibut
ion
S
tool
cul
ture
E
xper
t op
inio
n A
ltPer
t 0.0
97, 0
.132
, 0.
174
92 (
90%
CrI
21-
254)
S
tool
cul
ture
s
S
erol
ogy
Exp
ert
opin
ion
AltP
ert 0
.097
, 0.1
32,
0.17
4 92
(90
% C
rI 2
1-25
4)
Ser
olog
y te
sts
U
rine
m
icro
/cul
ture
/PC
R
Exp
ert
opin
ion
AltP
ert 0
.097
, 0.1
32,
0.17
4 92
(90
% C
rI 2
1-25
4)
Urin
e cu
lture
s
C
RP
& U
rate
A
bels
on e
t al
2006
(1)
; E
xper
t op
inio
n
AltP
ert 0
.16,
0.2
, 0.2
44
138
(90%
CrI
32-
375)
T
ests
F
BC
, ES
R
Abe
lson
et a
l 20
06 (
1);
Exp
ert
opin
ion
AltP
ert 0
.16,
0.2
, 0.2
44
138
(90%
CrI
32-
375)
T
ests
R
heum
atoi
d
fact
or
Abe
lson
et
al
2006
(1)
; E
xper
t op
inio
n
AltP
ert 0
.16,
0.2
, 0.2
44
138
(90%
CrI
32-
375)
T
ests
R
enal
func
tion
Exp
ert
opin
ion
AltP
ert 0
.16,
0.2
, 0.2
44
138
(90%
CrI
32-
375)
T
ests
B
lood
HLA
-B27
A
bels
on e
t al
2006
(1)
A
ltPer
t 0.1
6, 0
.2, 0
.244
13
8 (9
0% C
rI 3
2-37
5)
Tes
ts
X
-ra
y E
xper
t op
inio
n A
ltPer
t 0.0
12, 0
.095
, 0.
304
59 (
90%
CrI
7-2
81)
X-r
ays
U
ltras
ound
E
xper
t op
inio
n A
ltPer
t 0.0
17, 0
.034
, 0.
062
23 (
90%
CrI
5-7
2)
Ultr
asou
nds
M
RI
Exp
ert
opin
ion
AltP
ert 0
.002
, 0.0
1, 0
.03
6 (9
0% C
rI 1
-29)
M
RIs
Spe
cial
ist v
isits
A
bels
on e
t al
2006
(1)
157
assu
med
da
ta a
nd
base
d on
H
annu
et a
l 20
02 (
8)
Ref
erra
l to
rheu
mat
olog
ist
20%
who
vi
sit a
GP
are
re
ferr
ed
AltP
ert 0
.16,
0.2
, 0.2
44
138
(90%
CrI
32-
375)
R
efer
rals
R
efer
ral d
istr
ibut
ion
mul
tiplie
d by
GP
vis
it ou
tput
dis
trib
utio
n
Spe
cial
ist v
isits
/yea
r 20
% o
f re
ferr
ed h
ave
2 vi
sits
per
ye
ar
AltP
ert 0
.223
, 0.2
4,
0.25
8 16
7 (9
0% C
rI 3
9-44
5)
Spe
cial
ists
vi
sits
S
peci
alis
t dis
trib
utio
n m
ultip
lied
by G
P
visi
t ou
tput
dis
trib
utio
n
New
ong
oing
illn
ess
Leiri
salo
-R
epo
et a
l 19
97 (
12);
H
annu
et a
l 20
05 (
9)
AltP
ert 0
.23,
0.5
, 0.7
7 32
9 (9
0% C
rI 7
4-99
9)
Cas
es
New
ong
oing
illn
ess
dist
ribut
ion
mul
tiplie
d by
GP
vis
it ou
tput
+ h
ospi
talis
atio
n ou
tput
di
strib
utio
ns
Day
s of
lost
pai
d ac
tiviti
es
Tow
nes
et a
l 20
08 (
14)
AltP
ert 1
8.49
, 20.
15,
21.9
1 17
757
(90%
CrI
418
9-46
649)
D
ays
“ReA
sym
ptom
s in
terf
ered
with
usu
al
activ
ities
”. P
rodu
ctiv
ity d
istr
ibut
ion
mul
tiplie
d by
inci
denc
e ou
tput
dis
trib
utio
n.
Day
s of
lost
pai
d w
ork
Tow
nes
et a
l 20
08 (
14)
AltP
ert 2
.59,
3.3
7, 4
.3
2939
(90
% C
rI 6
96-
7959
) D
ays
“Mis
sed
wor
k be
caus
e of
ReA
sym
ptom
s”.
Pro
duct
ivity
dis
trib
utio
n m
ultip
lied
by
inci
denc
e ou
tput
dis
trib
utio
n.
Lost
pai
d w
ork
from
on
goin
g ill
ness
10
98 (
95%
CI 2
47-3
441)
D
ays
Ong
oing
illn
ess
dist
ribut
ion
mul
tiplie
d by
lo
st p
aid
wor
k di
strib
utio
n
158
References
1. Abelson, P., M. Forbes, and G. Hall. 2006. The annual cost of foodborne illness in Australia. In Australian Government Department of Health and Ageing, Canberra. 2. Australian Institute of Health and Welfare. Date, 2015, Separation statistics by principal diagnosis (ICD-10-AM 7th edition), Australia, 2011-12 to 2012-13. Available at: https://reporting.aihw.gov.au/Reports/openRVUrl.do. Accessed June, 2015. 3. Australian Institute of Health and Welfare. Date, 2017, Separation statistics by principal diagnosis (ICD-10-AM 7th edition), Australia, 2013-14 to 2014-15. Available at: http://www.aihw.gov.au/hospitals-data/principal-diagnosis-data-cubes/. Accessed, 2015. 4. Canavan, C., J. West, and T. Card. 2014. Review article: the economic impact of the irritable bowel syndrome. Aliment Pharmacol Ther. 40:1023-34. 5. Department of Health. Date, 2017, National Notifiable Disease Surveillance System. Notifications of a selected disease by age group, sex and year. Available at: http://www9.health.gov.au/cda/source/rpt_5_sel.cfm. Accessed, 2015. 6. Flik, C. E., W. Laan, A. J. Smout, B. L. Weusten, and N. J. de Wit. 2015. Comparison of medical costs generated by IBS patients in primary and secondary care in the Netherlands. BMC Gastroenterol. 15:168. 7. Ford, L., M. Kirk, K. Glass, and G. Hall. 2014. Sequelae of foodborne illness caused by 5 pathogens, Australia, circa 2010. Emerg Infect Dis. 20:1865-71. 8. Hannu, T., L. Mattila, H. Rautelin, P. Pelkonen, P. Lahdenne, A. Siitonen, and M. Leirisalo-Repo. 2002. Campylobacter-triggered reactive arthritis: a population-based study. Rheumatology (Oxford). 41:312-8. 9. Hannu, T., L. Mattila, A. Siitonen, and M. Leirisalo-Repo. 2005. Reactive arthritis attributable to Shigella infection: a clinical and epidemiological nationwide study. Ann Rheum Dis. 64:594-8. 10. Kirk, M., L. Ford, K. Glass, and G. Hall. 2014. Foodborne illness, Australia, circa 2000 and circa 2010. Emerg Infect Dis. 20:1857-64. 11. Kirk, M., C. McKercher, and G. Hall. 2011. Gastroenteritis in Australia: report of the National Gastroenteritis Survey II 2008. In OzFoodNet and the National Centre for Epidemiology and Population Health, Canberra. 12. Leirisalo-Repo, M., P. Helenius, T. Hannu, A. Lehtinen, J. Kreula, M. Taavitsainen, and S. Koskimies. 1997. Long-term prognosis of reactive salmonella arthritis. Ann Rheum Dis. 56:516-20. 13. Marshall, J. K., M. Thabane, M. R. Borgaonkar, and C. James. 2007. Postinfectious irritable bowel syndrome after a food-borne outbreak of acute gastroenteritis attributed to a viral pathogen. Clin Gastroenterol Hepatol. 5:457-60. 14. Townes, J. M., A. A. Deodhar, E. S. Laine, K. Smith, H. E. Krug, A. Barkhuizen, M. E. Thompson, P. R. Cieslak, and J. Sobel. 2008. Reactive arthritis following culture-confirmed infections with bacterial enteric pathogens in Minnesota and Oregon: a population-based study. Ann Rheum Dis. 67:1689-96. 15. Uotila, T. M., J. A. Antonen, A. S. Paakkala, J. T. Mustonen, and M. M. Korpela. 2013. Outcome of reactive arthritis after an extensive Finnish waterborne gastroenteritis outbreak: a 1-year prospective follow-up study. Clin Rheumatol. 32:1139-45.
159
Supplementary material 2: Sources of data for costing health care services
General practitioner visits
We estimated the probability that an incident case of Salmonella would consult a general
practitioner (GP) using weighted data from the National Gastroenteritis Survey II (NGSII) (7)
of 0.367 (95% Credible Intervals 0.246-0.501).
We adopted the assumptions of the earlier Abelson study for Australia (1) for irritable bowel
syndrome (IBS) and reactive arthritis (ReA) following Salmonella infection. For IBS we
assumed 4.5 visits (95% CrI 4.27-4.73) per patient, which was based on data from Bettering
the Evaluation of Care and Health (BEACH) program (11). For ReA, we assumed 20% visited
a GP for 4 visits, based on Hannu et al (5), resulting in a probability of 0.8 (95% CrI 0.66-0.89).
We used 95% credible intervals about these point estimates to reflect uncertainty in the
assumptions.
We assumed a normal consult visit for Salmonella and that 25% of GP visits for IBS and ReA
would be long consults and 75% would be normal consults. The costs for a normal consult of
$37.29 and a long consults of $72.06, calculated by dividing total benefits by services from
Medicare item reports(4) for Medicare Benefits Schedule (MBS) (3) item number 23 and item
number 36 respectively for the calendar year of 2015, were considered unrepresentative of the
true cost for society. We therefore adopted an average cost of $80 for a normal consult and
$110 for a long consult.
Emergency department visits
As with GP visits, we used weighted data from the NGSII to estimate the probability that an
incident case of foodborne Salmonella visited the Emergency department (ED), but was not
admitted to hospital, a probability of 0.124 (95% CrI 0.06-0.228) for ED visits.
For ED presentation costs we used an estimate from 2009/10 in New South Wales of $396
multiplied by urgency and disposition group triage weights (8). We used ED Only Triage 1-5
cost weights, where people in triage category 1 are categorised as having an immediate life-
threatening condition and people in triage category 5 are categorised as having a less urgent
condition. We weighted 5 the heaviest and 1 the lightest, to calculate a weighted average of
0.87. This equated to a total ED presentation cost of $345.31.
Hospital costs
Hospital cost data were extracted as Australian Refined Diagnosis Related Groups (AR-DRG)
costs and ALOS as published by the Independent Hospital Pricing Authority for 2013/14.(6)
For Salmonella, we used AR-DRG G67B for age groups 0-4, 5-19, and 20-64 and AR-DRG
160
67A for the age group 65+. We believe this is a conservative cost estimate as the ALOS we
extracted from AIHW was higher than the ALOS for these DRG codes. For IBS, we used AR-
DRG G67B costs for age groups 5-19, 20-64, and 65+, and AR-DRG G67A for age group 0-4
due to the longer ALOS in this age group. For ReA, we used AR-DGR I66B for all age groups.
See Table S2.1 for ALOS and Costs.
Table S2.1: AR-DRG codes used, average length of stay (ALOS), and costs, 2013-14
AR-DRG
Code
Description ALOS Cost
G67A Oesophageal, gastroenteritis, with complications 4.46 $7,054
G67B Oesophageal, gastroenteritis, without
complications
1.55 $2,328
I66B Inflammatory Musculoskeletal Disorders without
catastrophic or severe complications
4.04 $7,138
Treatments
To estimate treatments or medications taken for foodborne Salmonella infection, we used data
from the NGSII weighted for severity of diarrhoea by age group as with GP and ED visits (Table
2). We used expert clinical opinion to estimate that 40% (CrI 38.5%-41.6%) of IBS cases
would take medication (Table 3). For ReA, we used prior Australian assumptions (1), the
literature (12), and expert clinical opinion to estimate the proportion of cases that would receive
each of the medications or treatments in Table 4.
Costs for medications and treatments extracted from either the Pharmaceutical Benefits
Schedule (PBS) or from Chemist Warehouse (https://www.chemistwarehouse.com.au) for
Salmonella, IBS, and ReA can be found in Tables S2.2-S2.4.
Table S2.2: Salmonella medications and treatments, relevant PBS item numbers and brands,
and average estimated costs, 2015
Treatment PBS item number and any
brand costs taken into
account if applicable
Chemist
Warehouse
costs
used?
Average
estimated
cost
Antibiotics $11.36
Amoxycillin 1884E, 1886G 1887H, 1888J,
1889K, Amoxil brand
No $7.80
161
Trimethaprim-
sulphamethoxazole
2951H, 3103H, Septin Forte
brand
No $9.86
Metronidazole 1621H, 1630T, 1636D, 1642K,
Flagyl brand
No $11.04
Ciprofloxacin 1208N, 1209P, Ciproxin 250
brand
No $17.85
Ceftriaxone 1783W, 1784X, 1785Y, 1788D No $11.63
Azithromycin Yes $9.99
Diarrhoea relief $11.60
Electrolyte Yes $10.99
Loperamide 10889D, 10592L, 1571Q,
Immodium brand
Yes $14.34
Diphenoxylate-atropine 2501P No $9.46
Pain relief $10.02
Paracetamol & codeine 1215Y, 3316M, 10186D, 4170L,
4171M, 4275B, Panadeine Forte
brand
No $10.61
Paracetamol (Dymadon) Yes $9.19
Paracetamol 10582Y, 1770E, 3348F, 3349G,
5196L
Yes $7.12
Ibuprofen (Nurofen) Yes $8.99
Tramadol hydrochloride 8523N, Tramal SR 100 brand No $14.19
Nausea relief $15.46
Metoclopramide 1206L, Maxalon brand No $12.27
Prochlorperazine 2369Q, 2893G, Stemetil brand No $10.44
Promethazine 1948M, 3374N, 3488N No $30.16
Antacid Yes $8.99
Cramp relief $17.23
Hyoscine butylobromide 3473T Yes $17.23
Table S2.3: IBS medications and treatments, relevant PBS item numbers and brands, and
average estimated costs, 2015
Treatment PBS item number and any
brand costs taken into
account if applicable
Chemist
Warehouse
Average
estimated
cost
162
costs
used?
Average IBS treatment cost $72.65
Psyllium fibre Yes $19.99
Loperamide 10889D, 10592L, 1571Q,
Immodium brand
Yes $14.34
Prochlorperazine 2369Q, 2893G, Stemetil brand No $10.44
Hyoscine butylobromide 3473T Yes $17.23
Mebeverine hydrochloride 4328T, Colofac brand Yes $27.44
Rifaximin 10001J No $481.08
Colestyramine 2967E, 9249T No $55.27
Antidepressants
Sertraline 2236Q, 8836C, 2237R, 8837D No $7.05
Citalopram 8702B, 8703C, 8220P No $6.48
Escitalopram 8701Y, 9433L, 10181W, 8700X,
9432K
No $14.41
Paroxetine 2242B No $11.29
Fluoxetine 1434L, 8270G No $15.15
Fluvoxamine 8512B, 8174F No $10.87
Table S2.4: Reactive arthritis medications and treatments, relevant PBS item numbers and
brands, and average estimated costs, 2015
Treatment PBS item number and any
brand costs taken into
account
Chemist
Warehouse
costs
used?
Average
estimated
cost
Antibiotics As described in Table 1 $11.36
NSAID (Naproxen) Yes $10.50
Eye drops Yes $8.99
Prednisone 1934T, 1935W, 1936X,
Panafcorte brand
No $7.38
Inter-articular glucocorticoid
(Beetamethosone)
2694T No $20.75
DMARD (Methotrexate)*
11288D, 11283W, 11275K,
1622J, 11268C, 2396D, 4502Y,
No $87.65
163
4512L, 7250N, 7251P, 11295L,
2395C, 2272N
DMARD (Infliximab)* 10057H, 10067W, 10184B,
10196P, 4284L, 5753T, 5754W,
5755X, 5756Y, 5757B, 5758C,
6397Q, 6448J, 6496X, 9612X,
9613Y, 9617E, 9654D, 9674E
Yes $3,228.79
Joint Aspiration No $76.00
*Assumed 80% of those on DMARDs would be prescribed Methotrexate and 20% would be
prescribed Infliximab
Pathology and Imaging
For Salmonella, we extracted a cost of $45.19 for stool microscopy, culture, and sensitivity
(MCS) and $36.58 for polymerase chain reaction (PCR) by dividing total benefits by services
from Medicare item reports (4) for MBS (3) item number 69345 and item number 69496
respectively for the calendar year of 2015. We assumed 45% of tests would be MCS only, 9%
would be PCR only, and 46% would be both MCS and PCR (9).
Assumptions for the proportion of IBS cases undergoing pathology testing and imaging were
based on expert clinical opinion. We assumed that everyone who had an endoscopy would
also have anaesthesia and a biopsy. We extracted costs for these tests by dividing total
benefits by services for each item number from Medicare item reports (4) for the calendar year
of 2015. Item numbers and costs are detailed in Table S2.5.
Table S2.5: IBS Pathology and imaging, Medicare Benefits Schedule item numbers, and
estimated cost, 2015
Pathology test or Imaging MBS item
number(3)
Estimated cost
Stool MCS 69345 $45.19
FBC 65070 $14.13
ESR 65060 $6.56
LFT 66512 $14.75
CRP 66500 $8.17
Coeliac disease screening 71163 $21.12
Abdominal X-ray 58900 $31.60
Abdominal Ultrasound 55036 $103.39
Endoscopy 30473 $96.47
164
Anaesthesia for endoscopy 20902 $111.85
Biopsy 72818 $89.82
We used the prior Australian estimates (1) and expert clinical opinion to estimate the proportion
of ReA cases receiving pathology testing and imaging. We extracted costs for these tests by
dividing total benefits by services for each item number from Medicare item reports (4) for the
calendar year of 2015. Item numbers and costs are detailed in Table S2.6.
Table S2.6: ReA Pathology and Imaging, Medicare Benefits Schedule item numbers, and
estimated cost, 2015
Pathology test or Imaging MBS item
number(3)
Estimated cost
Stool MCS 69345 $45.19
IgG, IgM & IgA 71071 $26.17
Urinalysis 69333 $17.39
CRP & Urate 66503 $9.86
FBC 65070 $14.13
ESR 65060 $6.56
Rheumatoid factor 71106 $9.60
Renal Function with imaging
& 2 blood samples
12527 $71.92
Blood HLA-B27 71147 $34.61
Lumbosacral X-ray 58106 $75.98
Lower limb ultrasound 55834 $78.04
MRI 63328 $380.42
We have not incorporated episode coning, an arrangement which places an upper limit on the
number of services an episode for which Medicare benefits are payable, into our cost
estimates. However, we took a conservative approach in estimating the number of tests
ordered, so believe this will balance out any underestimation by not taking episode coning into
account.
Specialist Visits
For IBS, we used the literature (2) and expert clinical opinion to estimate that 30% (95% CrI
21%-49%) of cases would visit a specialist. For ReA, we used past assumptions and the
literature to estimate that 20% of cases would be referred to a specialist and 20% of these
165
would have 2 visits per year, resulting in a distribution of 0.24 (95% CrI 0.223-0.258). For cases
with ongoing illness, we assumed all cases would visit a specialist, of which 20% would be
initial visits and 80% would be repeat visits.
The costs for an initial specialist visit of $128.16 and repeat visit of $63.19, calculated by
dividing total benefits by services from Medicare item reports (4) for Medicare Benefits
Schedule (MBS) (3) item number 110 and item number 116 respectively for the calendar year
of 2015, were considered unrepresentative of the true cost for society. We therefore adopted
an average cost of $315 for an initial visit and $166 for a repeat visit based on the Australian
Medical Association’s recommended fees (10).
References
1. Abelson, P., M. P. Forbes, and G. Hall. 2006. The annual cost of foodborne illness in
Australia. Australian Government Department of Health and Ageing, Canberra.
2. Canavan, C., J. West, and T. Card. 2014. Review article: the economic impact of the
irritable bowel syndrome. Aliment Pharmacol Ther. 40:1023-1034.
3. Department of Health. MBS Online. Available at:
http://www.mbsonline.gov.au/internet/mbsonline/publishing.nsf/Content/Home. . Accessed 7
June 2018.
4. Department of Human Services. Medicare Item Reports. Available at:
http://medicarestatistics.humanservices.gov.au/statistics/mbs_item.jsp. Accessed 7 June
2018.
5. Hannu, T., L. Mattila, H. Rautelin, P. Pelkonen, P. Lahdenne, A. Siitonen, and M.
Leirisalo-Repo. 2002. Campylobacter-triggered reactive arthritis: a population-based study.
Rheumatology (Oxford). 41:312-318.
6. Independent Hospital Pricing Authority. 2016. National Hospital Cost Data Collection,
Australian Public Hospitals Cost Report, Round 18 (Financial year 2013-14).
7. Kirk, M., C. McKercher, and G. Hall. 2011. Gastroenteritis in Australia: report of the
National Gastroenteritis Survey II 2008. OzFoodNet and the National Centre for Epidemiology
and Population Health, Canberra.
8. Reeve, R., and M. Haas. 2013. Estimating the Cost of Emergency Department
Presentations in NSW. In, vol. Working Paper 2014/01. Centre for Health Economics Research
and Evaluation. University of Technology, Sydney, Ultimo NSW.
9. Roper, K., S. Vilkins, K. Glass, and M. Kirk. 2017. Implications of culture independent
diagonstic testing (CIDT) on Salmonella surveillance in Australia. Australian National
University, Canberra.
166
10. Sivey, P. 2016, How much?! Seeing private specialists often costs more than you
bargained for. Available at: https://theconversation.com/how-much-seeing-private-specialists-
often-costs-more-than-you-bargained-for-53445. Accessed 3 July 2018.
11. The University of Sydney. 2017, Better the Evaluation and Care of Health (BEACH).
Available at: http://sydney.edu.au/medicine/fmrc/beach/. Accessed 7 Jun, 2018.
12. Uotila, T. M., J. A. Antonen, A. S. Paakkala, J. T. Mustonen, and M. M. Korpela. 2013.
Outcome of reactive arthritis after an extensive Finnish waterborne gastroenteritis outbreak: a
1-year prospective follow-up study. Clin Rheumatol. 32:1139-1145.
167
Supplementary materials 3: Estimated mean cost of illness, Salmonella, circa 2015,
Australia
TABLE S3.1: Estimated mean annual cost of illness (millions AUD) of health care usage, lost productivity, premature mortality, for acute and ongoing illness, circa 2015, Australia
Mean cost in millions AUD (90% CrI)
NTSa IBSa ReAa Totalb
Health care usage
Acute illness 23.8 (19.3-28.9) 5.7 (4.0-8.0) 2.0 (1.0-3.6) 31.6 (26.5-37.2)
Ongoing illness - 3.5 (1.8-6.9) 0.86 (0.34-1.7) 4.3 (2.7-6.5)
Lost productivity
Acute illness 22.0 (13.7-33.6) 2.1 (1.3-3.3) 3.1 (1.0-6.5) 27.2 (18.5-38.4)
Ongoing illness - 3.8 (1.8-6.9) 1.2 (0.37-2.8) 5.1 (2.7-8.4)
Premature mortality
Acute illness 79.0 (66.0-92.1) - - 79.0 (66.0-92.1)
Total costs
Acute illness 124.7 (107.4-143.1) 7.9 (5.3-11.3) 5.1 (2.0-10.0) 137.7 (119.7-157.0)
Ongoing illness - 7.3 (3.9-12.3) 2.1 (0.73-4.4) 9.4 (5.5-14.8)
Total 124.7 (107.4-143.1) 15.1 (9.5-23.0) 7.2 (2.4-14.2) 147.2 (127.8-167.9)
aNTS: non-typhoidal Salmonella; IBS: irritable bowel syndrome; ReA: reactive arthritis
bNumbers may not sum due to simulation and rounding
168
TABLE S3.2: Estimated mean annual cost of acute and ongoing illness in 1 year (millions AUD) by age group, circa 2015, Australia
Mean cost in millions AUD (90% CrI)
NTSa IBSa ReAa Totalb
Health care usage
0-4 years 4.3 (3.0-5.9) 0.004 (0.002-0.006) 0.16 (0.04-0.37) 4.5 (3.2-6.1)
5-19 years 2.9 (2.0-4.0) 1.7 (0.90-3.0) 0.56 (0.13-1.3) 5.2 (3.7-6.9)
20-64 years 8.8 (5.9-12.4) 6.0 (3.3-9.8) 1.8 (0.46-4.0) 16.6 (11.9-22.0)
65+ years 7.8 (5.1-11.0) 1.5 (0.80-2.4) 0.41 (0.10-0.93) 9.6 (6.8-13.0)
Lost Productivity
0-4 years 5.3 (2.3-10.0) 0.003 (0.001-0.004) 0.38 (0.07-0.78) 5.7 (2.6-10.3)
5-19 years 1.9 (0.46-4.4) 0.37 (0.17-0.65) 0.26 (0.05-0.61) 2.5 (1.0-5.0)
20-64 years 13.4 (6.7-22.8) 5.4 (2.7-9.4) 3.6 (0.73-8.4) 22.5 (13.9-33.6)
65+ years 1.4 (0.33-3.0) 0.20 (0.10-0.35) 0.13 (0.03-0.31) 1.7 (0.64-3.3)
Premature mortality
0-4 years 2.8 (2.1-3.5) - - 2.8 (2.1-3.5)
5-19 years 7.3 (5.7-8.8) - - 7.3 (5.7-8.8)
20-64 years 15.1 (11.6-18.7) - - 15.1 (11.6-18.7)
65+ years 53.9 (41.6-66.3) - - 53.9 (41.6-66.3)
Total costs
0-4 years 12.4 (8.5-18.1) 0.006 (0.004-0.009) 0.50 (0.11-1.1) 12.9 (8.9-18.6)
5-19 years 12.0 (9.4-15.3) 2.1 (1.1-3.6) 0.82 (0.09-1.9) 14.9 (11.9-18.6)
20-64 years 37.3 (27.7-49.8) 11.4 (6.0-19.1) 5.3 (1.2-12.2) 54.1 (41.2-70.0)
65+ years 63.0 (50.3-75.9) 1.6 (0.9-2.7) 0.54 (0.12-1.2) 65.1 (52.5-78.2)
aNTS: non-typhoidal Salmonella; IBS: irritable bowel syndrome; ReA: reactive arthritis
bNumbers may not sum due to simulation and rounding
169
TABLE S3.3: Estimated mean annual cost of acute and ongoing illness ($AUD) per case by age group, circa 2015, Australia
Mean cost AUD
NTSa IBSa ReAa Total
Health care usage only
0-4 years 209.17 905.15 314.42 217.70
5-19 years 199.67 439.31 297.20 366.26
20-64 years 200.67 500.86 312.14 386.87
65+ years 754.01 500.21 293.93 936.82
Total 254.69 480.42 297.22 385.73
Health care usage with lost productivity
0-4 years 451.10 1,457.92 925.03 476.91
5-19 years 320.19 530.18 432.12 532.25
20-64 years 486.25 942.31 922.75 889.34
65+ years 872.56 567.33 387.99 1,088.16
Total 482.66 784.35 722.37 725.81
Health care usage, lost productivity, and premature mortality
0-4 years 592.44 1,457.92 925.03 618.25
5-19 years 846.17 530.18 432.12 1,058.22
20-64 years 848.07 942.31 922.75 1,251.17
65+ years 6,175.07 567.33 387.99 6,390.67
Total* 1,339.11 784.35 722.37 1,582.21
aNTS: non-typhoidal Salmonella; IBS: irritable bowel syndrome; ReA: reactive arthritis
170
The following supplementary information will be part of the manuscript submission as a
supplement to the paper.
Ford L, Glass K, Williamson DA, Sintchenko V, Robson JMB, Stafford R, Kirk D. Cost of whole
genome sequencing for non-typhoidal Salmonella enterica. To be submitted 2019.
National notification numbers
In 2017, 5687/16051 (35%) of non-typhoidal Salmonella notifications were serotyped as
Typhimurium (Department of Health 2018) (Table S1).
Table S1: National number of Salmonella spp. notifications by type, Australia, 2017
Number of notifications
Salmonella Typhimurium 5687
Non-Typhimurium Salmonella 8718
Unspecified 1646
Total 16051
Outbreak scenarios
We obtained dates of illness onset and case numbers for several outbreaks occurring over the
last 20 years in Australia from Queensland Health. We then generated epidemiological curves
and cumulative outbreak costs based on current laboratory subtyping methods (serotyping and
MLVA) compared with whole genome sequencing (WGS) and polymerase chain reaction
(PCR) testing for a point source outbreak and two prolonged outbreaks.
Point source outbreak: Salmonella Typhimurium outbreak in January 2015
In this outbreak, there were 123 cases of Salmonella Typhimurium with illness onsets over 6
days (Figure S1). As this was an outbreak of Salmonella Typhimurium, serotyping and MLVA
would have been used to type the isolates. As in our simulated point source outbreak,
cumulative outbreak costs were slightly less if WGS had been used, costing USD 152,123
(90% CrI 92,528-257,067) for serotyping and MLVA, compared with USD 150,200 (90% CrI
90,894-255,326) for WGS or USD 139,163 (90% 79,922-244,329) for PCR-only (Figure S2).
171
Figure S1: Epidemiological curve of Salmonella Typhimurium outbreak in January 2015,
Queensland Australia
Figure S2: Cumulative outbreak costs using serotyping and MLVA compared to WGS in a
Salmonella Typhimurium outbreak in January 2015, Queensland Australia
Prolonged outbreak: Salmonella Bovismorbificans outbreak in May and June 2001
In this outbreak, there were 29 cases of Salmonella Bovismorbificans with illness onsets over
44 days (Figure S3). As with the prolonged outbreak scenario, cumulative outbreak costs with
WGS (USD 35,465 (90% CrI 21,504-60,616)) were higher than with serotyping (USD 34,237
(90% CrI 20,308-59,395)) or PCR (USD 32,863 (90% CrI 18,927-57,974)) (Figure S4). If WGS
data were able to detect the outbreak earlier, and an intervention was put in place earlier, WGS
would result in a cost savings. However, the difference in costs is not as large at our first
modelled earlier intervention point (2 weeks) as was seen in our first modelled earlier
0
10
20
30
40
50
60
03‐Jan‐15 04‐Jan‐15 05‐Jan‐15 06‐Jan‐15 07‐Jan‐15 08‐Jan‐15
Number of cases
Date of illness onset
$0
$20,000
$40,000
$60,000
$80,000
$100,000
$120,000
$140,000
$160,000
03‐Jan‐15 04‐Jan‐15 05‐Jan‐15 06‐Jan‐15 07‐Jan‐15 08‐Jan‐15
Cumulative outbreak cost USD
Date of illness onset
Serotyping and MLVA WGS PCR
172
intervention points in our simulated prolonged outbreak. This is due to the length of the
outbreak and the shape of the epidemiological curve.
Figure S3: Epidemiological curve of Salmonella Bovismorbificans outbreak in May and June
2001, Queensland Australia
Figure S4: Cumulative outbreak costs using serotyping compared to WGS, with earlier
modelled interventions, in a Salmonella Bovismorbificans outbreak in May and June 2001,
Queensland Australia
0
1
2
3
4
5
16‐M
ay‐01
18‐M
ay‐01
20‐M
ay‐01
22‐M
ay‐01
24‐M
ay‐01
26‐M
ay‐01
28‐M
ay‐01
30‐M
ay‐01
01‐Jun‐01
03‐Jun‐01
05‐Jun‐01
07‐Jun‐01
09‐Jun‐01
11‐Jun‐01
13‐Jun‐01
15‐Jun‐01
17‐Jun‐01
19‐Jun‐01
21‐Jun‐01
23‐Jun‐01
25‐Jun‐01
27‐Jun‐01
Number of cases
Date of illness onset
$0
$5,000
$10,000
$15,000
$20,000
$25,000
$30,000
$35,000
$40,000
16‐M
ay‐01
18‐M
ay‐01
20‐M
ay‐01
22‐M
ay‐01
24‐M
ay‐01
26‐M
ay‐01
28‐M
ay‐01
30‐M
ay‐01
01‐Jun‐01
03‐Jun‐01
05‐Jun‐01
07‐Jun‐01
09‐Jun‐01
11‐Jun‐01
13‐Jun‐01
15‐Jun‐01
17‐Jun‐01
19‐Jun‐01
21‐Jun‐01
23‐Jun‐01
25‐Jun‐01
27‐Jun‐01Cumulative outbreak cost USD
Date of illness onset
Serotyping WGS
WGS, 2 week earlier intervention WGS, 4 week earlier intervention
PCR
173
As this was a Salmonella Bovismorbificans outbreak occurring in 2001, the isolates also were
phage typed. If we added phage typing costs on top of the serotyping costs, the cumulative
outbreak costs for WGS would likely be lower.
Prolonged outbreak: Salmonella Saintpaul outbreak in April 2011
In this outbreak, there were 17 cases of Salmonella Saintpaul cases occurring over 39 days
(Figure S5). As with the previous example and the simulated prolonged outbreak scenario,
cumulative outbreak costs with WGS (USD 20,689 (90% CrI 12,655-35,477) were higher than
with serotyping (USD 20,011 (90% CrI 11,969-34,824)) or PCR (USD 19,159 (90% CrI 11,133-
33,982)) (Figure S6). If an intervention could be put into place and prevent just one case, then
WGS would result in cost savings.
Figure S5: Epidemiological curve of Salmonella Saintpaul outbreak September–November
2005, Queensland Australia
0
1
2
3
4
29‐Sep
‐05
01‐Oct‐05
03‐Oct‐05
05‐Oct‐05
07‐Oct‐05
09‐Oct‐05
11‐Oct‐05
13‐Oct‐05
15‐Oct‐05
17‐Oct‐05
19‐Oct‐05
21‐Oct‐05
23‐Oct‐05
25‐Oct‐05
27‐Oct‐05
29‐Oct‐05
31‐Oct‐05
02‐Nov‐05
04‐Nov‐05
06‐Nov‐05
Number of cases
Date of illness onset
174
Figure S6: Cumulative outbreak costs using serotyping compared to WGS in a Salmonella
Saintpaul outbreak in 2005, Queensland Australia
References
Department of Health 2018. Salmonella public data set. Retrieved 21 November 2018 from
http://www9.health.gov.au/cda/source/pub_salmo.cfm.
$0
$5,000
$10,000
$15,000
$20,000
$25,000
29‐Sep
‐05
01‐Oct‐05
03‐Oct‐05
05‐Oct‐05
07‐Oct‐05
09‐Oct‐05
11‐Oct‐05
13‐Oct‐05
15‐Oct‐05
17‐Oct‐05
19‐Oct‐05
21‐Oct‐05
23‐Oct‐05
25‐Oct‐05
27‐Oct‐05
29‐Oct‐05
31‐Oct‐05
02‐Nov‐05
04‐Nov‐05
06‐Nov‐05
Cumulative outbreak costs USD
Date of illness onset
Serotyping WGS PCR
175
Appendix 4. Supplementary materials for chapter 6 The following supplementary information was part of the manuscript submission and published
online as a supplement to the paper.
Ford L, Carter GP, Wang Q, Seemann T, Sintchenko V, Glass K, Williamson DA, Howard P,
Valcanis M, Castillo CFS, Sait M, Howden BP, Kirk MD. Incorporating whole-genome
sequencing into public health surveillance: lessons from prospective sequencing of Salmonella
Typhimurium in Australia. Foodborne Pathogens and Disease. 2018;15(3): 161-167, doi:
10.10189/fpd.2017.2352.
Supplementary Data
Isolates linked through multilocus variable-number tandem-repeat analysis (MLVA) and epidemiological data were as-sociated with 11 identified clusters or point-source outbreaks(Supplementary Fig. S1).
Outbreak investigations indicated that 5 of these 11 events,which occurred over a large geographic area between Januaryand March 2016, were related to a common egg grading fa-cility. The details of these outbreak investigations, as well astwo additionally linked investigations, are discussed else-where (Ford et al., 2017). The whole-genome sequencing(WGS) data show that there were an additional nine isolateswith illness onsets between February and May that werewithin eight single-nucleotide polymorphisms (SNPs) ofknown outbreak isolates. While it is possible that the twoisolates with illness onsets around the same time as theAustralian Capital Territory (ACT) outbreaks in Februarywere unknowingly linked to one of the two implicated foodpremises, it is unlikely that the other seven isolates with ill-ness onsets in later months had an unmentioned associationwith the food premises. The genetic relatedness of these casesto outbreak cases suggests that the source of illness may bethe same as the suspected source of illness (eggs) of theoutbreak isolates in this clade.
Fifteen isolates were linked to an outbreak associated witha food premises (Outbreak 6) in May 2016 identified through
case interviews. Cases in this outbreak reported eating at thefood premises over a period of 11 d and those who ate thereon the 11th day had a different MLVA profile (03-10-14-11-496) and were *90 SNPs apart from those who reportedeating at the premises the previous 10 d (MLVA: 03-12-18-14-523). The source of the outbreak is unknown. An addi-tional two isolates were linked by WGS to cases from the first10 d and one isolate was linked by WGS to the cases from the11th day who did not mention eating at the food premisesduring their interview. Illness onsets for these three caseswere within 2 weeks of the outbreak.
Six isolates with no SNP differences (Outbreak 7) werelinked to an outbreak in a private residence in February 2016identified through case interviews. The source of the outbreakwas unknown.
There were two sets of siblings included, which—based onillness onset dates—were likely transmitted from person toperson (Clusters 1 and 2).
There were two isolates from residents of the ACT, whohad travelled interstate during their incubation and werecases in a known outbreak in that state (Outbreak 8).
Finally, there were five isolates from four cases who werepossibly associated with a common food premises, but therewas insufficient epidemiological and environmental evidenceto implicate the food premises (Outbreak 9).
176
SUPPLEMENTARY FIG. S1. Maximum likelihood core genome SNP phylogeny of Salmonella Typhimurium isolates withepidemiological data, ACT, January to June 2016. Clusters identified by WGS are highlighted in the tree. Clusters and outbreaksidentified by epidemiological data are labeled in the tree. Figure created with Interactive Tree of Life (https://itol.embl.de).
177
178
The following supplementary information was part of the manuscript submission and published
online as a supplement to the paper
Ford L, Wang Q, Stafford R, Ressler KA, Norton S, Shadbolt C, Hope K, Franklin N, Krsteski
R, Carswell A, Carter GP, Seemann T, Howard P, Valcanis M, Castillo CFS, Bates J, Glass K,
Williamson DA, Sintchenko V, Howden BP, Kirk MD. Seven Salmonella Typhimurium
outbreaks in Australia linked by trace-back and whole-genome sequencing. Foodborne
Pathogens and Disease. 2018;15(5):285-292, doi: 10.1089/fpd.2017.2353.
Supplementary Information
Outbreak summaries
Australian Capital Territory (ACT)
In the ACT there were two small outbreaks of S. Typhimurium 03-26-13-08-523 in
February 2016. In the first outbreak there were 4 confirmed cases who were linked to
restaurant A and reported eating an eggs benedict dish. A public health officer inspected
restaurant A, with no food safety compliance issues identified. Three samples of egg,
spinach, and commercially produced hollandaise sauce were collected for testing. No
Salmonella was detected in any of the samples. In the second outbreak, there were 5
confirmed cases who were linked to restaurant B. An egg and lettuce sandwich was the most
frequently reported food among cases. A public health officer inspected restaurant B, with no
food safety compliance issues identified. Three food samples (boiled egg, egg and lettuce
sandwich, and shredded lettuce) were collected for testing. No Salmonella was detected in
any of the samples. Egg supplier details were obtained during both inspections and both
restaurant A and restaurant B used eggs produced by company X.
New South Wales (NSW)
In NSW there was one outbreak of S. Typhimurium 03-26-13-08-523 in October-
November 2015 and two in January 2016. In November 2015 a retrospective cohort study
was conducted into a large number of patrons with gastrointestinal illness related to a
degustation dinner prepared and consumed at Restaurant C. A total of 40 out of 60
individuals who were interviewed or surveyed met the case definition (Supplementary Table
S2). Seven cases from the cohort had clinical samples taken and all were confirmed as
Salmonella Typhimurium 03-26-13-08-523. Coriander mayonnaise, containing raw egg was
179
identified as a probable source of infection through the epidemiological investigation
(relative risk: 3.6; p value: 0.042). The NSW Food Authority conducted a basic inspection of
the premises on 6 November 2015, followed by a comprehensive inspection on 10 November
2015. The Food Authority discovered inadequate food handling practices: use of
unpasteurised eggs in dessert products did not reach adequate temperatures to ensure
pathogen reduction/kill step and separation of eggs was done by hand in the shell. Twelve
food samples (eggs, marinated chevre, double brie cheese, chilli jam, beetroot, micro herbs,
quail breast fillet, crème anglaise, crème patissiere, aioli, 2 x mayonnaise mixtures), and 6
environmental samples (whisk kitchen, kitchen aid x 2, aioli bench and sink, profiterole
bench and sink, boot swabs) were collected by the NSW Food Authority. No Salmonella was
detected in any of the samples. Only 7 of the food specimens, not including the mayonnaise,
were possible leftovers from the dinner. Egg supplier details were obtained and eggs were
produced by company X.
In one outbreak identified in January 2016, there were 203 cases were linked to a
bakery, of which 91 were confirmed with Salmonella and 81 of these were S. Typhimurium
03-26-13-08-523 (Supplementary Table S2). A survey of a sample of 100 suspected cases
identified chicken, pork and salad-filled rolls as the most commonly consumed foods. The
NSW Food Authority inspected the bakery at which time non-compliances with food safety
standards were identified such as lack of appropriate sanitising of utensils or equipment, other
cleanliness issues, and some evidence of rodent droppings. A prohibition order was served
and numerous food and environmental samples were collected for testing. Results of the
bacterial analysis showed the presence of Salmonella Typhimurium 3-26-13-08-523 in 9 food
samples including ready-to-eat salad items that were the basic ingredients of the filled rolls.
Salmonella Typhimurium 3-26-13-08-523 was also detected in 14 environmental samples.
The eggs used by the bakery were produced by company X.
180
A second outbreak was identified in January 2016 involving 2 cases at an aged care
facility. Investigations were unable to identify a potential food or source of infection. The
environmental investigation did not identify any issues, and no food specimens or
environmental samples were collected for testing.
Queensland
Two outbreaks of S. Typhimurium 03-26-13-08-523 infection were reported in
Queensland during February and March 2016 respectively. The first outbreak investigation
identified 12 cases of gastrointestinal illness, including six Queensland residents whom were
laboratory confirmed (Supplementary Table S2), linked to the consumption of French crepes
purchased from one of three market stalls operated by the same vendor. Investigations
identified that an egg batter used to make the crepes was not discarded after each event and
left-over batter was potentially used over a three day period. Food and environmental samples
collected the following week tested negative for bacterial pathogens. Invoice records indicate
the eggs used by the business during the outbreak were from company X. The second
outbreak involved 10 cases of Salmonella Typhimurium 03-26-13-08-524 infection among
persons who had attended an Italian Festival held in a community park over a 3 day period
(Supplementary Table S2). Investigations were unable to identify a potential food vehicle or
source of infection due to poor recall among cases and the time delay for the investigation.
The festival also consisted of market stalls for the sale of foods.
181
Supp
lem
enta
ry T
able
1
Supp
lem
enta
ry T
able
S2.
Cas
e de
finiti
ons u
sed
in o
utbr
eaks
of S. T
yphi
mur
ium
03-
26-1
3-08
-523
in th
e A
ustra
lian
Cap
ital T
errit
ory
(AC
T),
New
Sou
th W
ales
(NSW
), an
d Q
ueen
slan
d (Q
ld) i
nves
tigat
ed b
etw
een
Nov
embe
r 201
5 an
d M
arch
201
6.
Stat
e M
onth
and
ye
ar o
f in
vest
igat
ion
Sett
ing
Cas
e de
finiti
on
No.
of c
ases
N
o. o
f lab
-co
nfir
med
ca
ses
NSW
N
ov 2
015
Res
taur
ant
An
indi
vidu
al w
ho a
te o
r ser
ved
dinn
er a
t the
Res
taur
ant o
n 29
Oct
ober
20
15 a
nd su
bseq
uent
ly d
evel
oped
acu
te g
astro
ente
ritis
. 40
7
NSW
Ja
n 20
16
Bak
ery
Vom
iting
or d
iarr
hoea
follo
win
g co
nsum
ptio
n of
take
aw
ay fo
ods
purc
hase
d fr
om B
aker
y X
from
Wed
nesd
ay 2
2 Ja
nuar
y 20
16.
203
81
NSW
Ja
n 20
16
Age
d ca
re
faci
lity
Pers
ons w
ith d
iarr
hoea
AN
D/O
R v
omiti
ng w
ithin
a re
side
ntia
l age
d ca
re
faci
lity,
occ
urrin
g in
a 2
4 ho
ur p
erio
d, w
hich
can
not b
e at
tribu
ted
to a
kn
own
caus
e - e
.g. a
n ex
istin
g m
edic
al c
ondi
tion
or th
e us
e of
med
icat
ions
su
ch a
s ant
ibio
tics o
r ape
rient
s.
2 2
AC
T Fe
b 20
16
Res
taur
ant
An
indi
vidu
al w
ho a
te a
t the
Res
taur
ant o
n 12
/2/1
6 an
d su
bseq
uent
ly
deve
lope
d ac
ute
gast
roen
terit
is
5 4
Qld
Fe
b 20
16
Mar
ket
A p
erso
n w
ho a
ttend
ed a
ny o
f the
thre
e im
plic
ated
mar
kets
bet
wee
n 19
an
d 21
Feb
ruar
y 20
16 a
nd w
as e
ither
dia
gnos
ed w
ith S. T
yphi
mur
ium
03-
26-1
3-08
-523
infe
ctio
n or
atte
nded
the
mar
kets
with
a c
onfir
med
cas
e an
d de
velo
ped
acut
e ga
stro
ente
ritis
dur
ing
the
follo
win
g w
eek.
12
6
AC
T Fe
b 20
16
Res
taur
ant
A c
ase
of S. T
yphi
mur
ium
03-
26-1
3-08
-523
who
ate
at t
he R
esta
uran
t be
twee
n 24
/2/1
6 an
d 29
/2/1
6 an
d su
bseq
uent
ly d
evel
oped
acu
te
gast
roen
terit
is
5 5
Qld
M
ar 2
016
Fest
ival
A
per
son
who
atte
nded
the
Italia
n Fe
stiv
al b
etw
een
25 a
nd 2
7 M
arch
201
6 an
d w
as d
iagn
osed
with
S. T
yphi
mur
ium
03-
26-1
3-08
-523
infe
ctio
n.
10
10
182
Supp
lem
enta
ry T
able
2
Supp
lem
enta
ry T
able
S1.
Foo
d sa
mpl
es a
nd e
nviro
nmen
tal s
wab
s col
lect
ed in
the S.
Typ
him
uriu
m 0
3-26
-13-
08-5
23 o
utbr
eaks
in th
e A
ustra
lian
Cap
ital T
errit
ory
(AC
T), N
ew S
outh
Wal
es (N
SW),
and
Que
ensl
and
(Qld
) inv
estig
ated
bet
wee
n N
ovem
ber 2
015
and
Mar
ch 2
016.
St
ate
Mon
th a
nd
year
of
inve
stig
atio
n
Sett
ing
Food
sam
ples
col
lect
ed
Env
iron
men
tal s
wab
s co
llect
ed
Sam
ples
with
S. T
yphi
mur
ium
03
-26-
13-0
8-52
3 de
tect
ed
NSW
N
ov 2
015
Res
taur
ant
Mar
inat
ed c
hevr
e*; b
rie*;
be
etro
ot*;
chi
lli ja
m*;
mic
ro
herb
s (4)
*; q
uail
brea
st fi
llet
(2)*
; Who
le e
ggs;
crè
me
angl
aise
; crè
me
patis
sier
e; a
ioli;
m
ayon
nais
e (2
)
Whi
sk; s
tand
mix
ers (
2); a
ioli
benc
h an
d si
nk; p
rofit
erol
e be
nch
and
sink
; boo
t sw
abs
kitc
hen
Non
e
NSW
Ja
n 20
16
Bak
ery
Chi
cken
roll;
coo
ked
pork
mea
t; w
hite
rect
angu
lar c
ut m
eat;
red
rect
angu
lar c
ut m
eat;
chic
ken
shre
dded
(2);
pate
; Cae
sar s
alad
w
ith sl
iced
boi
led
eggs
; co
lesl
aw; t
abou
li; le
ttuce
sh
redd
ed; c
oria
nder
; cuc
umbe
r sl
iced
; tom
ato
slic
ed; c
arro
ts
shre
dded
; oni
ons s
liced
; bee
troot
sl
iced
; boi
led
eggs
(3);
chee
se
slic
ed; m
ayon
nais
e an
d m
arga
rine
mix
(2);
may
onna
ise
sauc
e (2
); fr
ozen
pat
e to
be
re-
cook
ed; c
hick
en st
uffin
g; w
hole
ra
w c
hick
en; w
hole
shel
l egg
s (tr
ay o
f 30)
; fro
zen
cook
ed p
ork;
fr
ozen
slic
ed w
hite
pro
cess
ed
mea
t; fr
ozen
slic
ed re
d
Boo
t sw
abs (
3); w
ash
basi
n;
sink
; coo
l roo
m (2
); be
nch;
fr
eeze
r; di
spla
y ca
bine
ts;
woo
den
chop
ping
boa
rds;
pla
stic
ch
oppi
ng b
oard
s; c
ompo
site
ut
ensi
ls; c
ompo
site
mix
ing
bow
ls; c
ompo
site
mic
row
ave
and
rice
cook
er; c
ompo
site
po
wer
poi
nts a
nd li
ght s
witc
hes;
ch
icke
n co
oker
(2);
chic
ken
skew
ers;
chi
cken
ute
nsils
; raw
ch
icke
n st
orag
e tu
b; ra
w c
hick
en
prep
sink
; chi
cken
seas
onin
g bu
cket
; woo
den
tabl
es; s
tove
; pr
oces
sed
mea
t kni
fe; w
indo
w
sill;
pat
e fr
idge
; gra
vy p
ot a
nd
uten
sils
; whi
sk
14 fo
od sa
mpl
es: c
hick
en ro
ll;
whi
te re
ctan
gula
r cut
mea
t; re
d re
ctan
gula
r cut
mea
t; ch
icke
n sh
redd
ed; C
aesa
r sal
ad w
ith
slic
ed b
oile
d eg
gs; l
ettu
ce
shre
dded
; cor
iand
er; c
ucum
ber
slic
ed; t
omat
o sl
iced
; car
rots
sl
iced
; oni
ons s
liced
; bee
troot
sl
iced
; boi
led
eggs
(3);
chee
se
slic
ed
9 en
viro
nmen
tal s
wab
s: b
oot
swab
s (3)
; sin
k; c
ool r
oom
; co
mpo
site
mix
ing
bow
l; ch
icke
n sk
ewer
s; ra
w c
hick
en p
rep
sink
; pa
te fr
idge
183
proc
esse
d m
eat;
froz
en c
hick
en
schn
itzel
; fro
zen
pate
(2);
mar
garin
e; c
rack
ed b
lack
pe
pper
; red
food
col
our
NSW
Ja
n 20
16
Age
d ca
re
faci
lity
No
sam
ples
col
lect
ed
No
swab
s col
lect
ed
-
AC
T Fe
b 20
16
Res
taur
ant
Who
le e
ggs (
3); s
pina
ch;
com
mer
cial
ly p
rodu
ced
holla
ndai
se sa
uce
No
swab
s col
lect
ed
Non
e
Qld
Fe
b 20
16
Mar
ket
Panc
ake
batte
r; ch
icke
n; h
am;
spin
ach;
che
ese;
chi
cken
cre
pe
Prep
arat
ion
benc
h (k
itche
n);
hand
mix
er; c
repe
spre
ader
; ba
tter b
ottle
; cut
ting
boar
d
Non
e
AC
T Fe
b 20
16
Res
taur
ant
Boi
led
egg;
egg
and
lettu
ce
sand
wic
h; sh
redd
ed le
ttuce
N
o sw
abs c
olle
cted
N
one
Qld
M
ar 2
016
Fest
ival
N
o sa
mpl
es c
olle
cted
N
o sw
abs c
olle
cted
-
*Pos
sibl
e le
ft ov
er fo
ods f
rom
the
day(
s) o
f the
out
brea
k.
184
185
Appendix 5. Supplementary materials for chapter 7 The following supplementary materials were part of the manuscript submission and published
online as a supplement to the paper
Ford L, Ingle D, Glass K, Veitch M, Williamson DA, Harlock M, Gregory J, Stafford R, French
N, Bloomfield S, Grange Z, Conway ML, Kirk MD. Whole-genome sequencing of Salmonella
Mississippi and Typhimurium Definitive Type 160, Australia and New Zealand. Emerging
Infectious Diseases. 2019;25(9):1690-1697, doi: 10.3201/eid2509.181811.
Article DOI: https://doi.org/10.3201/eid2509.181811
Whole-Genome Sequencing of Salmonella Mississippi and Typhimurium Definitive Type 160, Australia and New Zealand
Appendix
Methods
Salmonella Mississippi Sampling Strategy
We sampled from 529 Salmonella Mississippi human isolates with a Tasmanian postcode
at the Microbiological Diagnostic Unit Public Health Laboratory (MDU PHL) and isolated
between 2011 and 2015. We excluded any isolate with an indication of overseas travel (n = 2),
sorted by isolation date, and then sampled every 1 in 15 isolates (n = 36). When comparing the
characteristics of sampled isolates to the population, there was a higher proportion of males in
the sample (Appendix Table 1).
Therefore, we re-sampled, sorting by isolation date and sampling every 2nd in 15 isolates
(n = 36). As the characteristics of this sample were closer to the population, they were chosen for
sequencing (Appendix Table 2, Appendix Figures 2, 3).
We also sampled from 74 isolates from other states that were isolated between 2011 and
2015 and at MDU PHL. We excluded isolates with an indication of overseas acquisition (n = 12).
We selected the 1 isolate available from the Australian Capital Territory (ACT), 1 from South
Australia (SA), and 1 from Queensland (Qld), all with travel to Tasmania reported. There were 6
isolates with a New South Wales postcode and 2 isolates with a Western Australia postcode. We
randomly selected 1 from each of these states, both with travel to Tasmania reported. There were
51 isolates with a Victorian postcode. We sorted by postcode and selected 1 in 5, sampling 10
isolates from Victoria. The characteristics of cases with selected isolates compared to all isolates
in other states is in Appendix Table 3.
186
In addition, we opportunistically sampled 12 Salmonella Mississippi human isolates that
were at Queensland Health Forensic and Scientific Services, which were isolated between 2004
and 2009. Of these, 42% were from males, and the median age was 33.5. Some isolates were
from cases involved in an unpublished 2008 case–control study. The isolates were sent to MDU
PHL for sequencing.
Additional Genomics Information
As there is no publicly available complete Salmonella Mississippi genome, a local
reference was assembled using one of the MDU PHL Salmonella Mississippi isolates.
Preliminary analysis showed the Salmonella Mississippi genomes had similar QC stats and the
oldest sequenced strain (AUSMDU00020775) was selected (2000). Illumina reads of the isolate
were assembled using Unicycler (1) using a minimum contig length on 200 bp. The resulting
assembly was used as the reference for the analysis of the core genome. AUSMDU00020775
assembly comprised 92 contigs, with total number of reference bases 4672632 and an N50 of
366033.
We looked at 11 publicly available draft assemblies of Salmonella Mississippi (2–4). The
sequence type (ST) of the publicly available draft assemblies were determined using mlst (v2.11-
dev) (https:/github.com/tseemann/mlst) in conjunction with the “senterica” MLST scheme. Of
note, the majority of the public and the MDU PHL Salmonella Mississippi isolates did not have a
known ST. One publicly available isolate (Mississippi_BCW_4007) (4) had no alleles the same
as the other Salmonella Mississippi genomes, indicative that this was a highly divergent strain of
Salmonella Mississippi. This isolate was excluded from further analysis. Nine of the remaining
included publicly available draft assemblies were from soil or Takahe from 2011–2013 in New
Zealand (3) and 1 was from a human in 2010 from the United States of America (2).
Results
Single-Nucleotide Polymorphisms (SNPs) between Australian and New Zealand Isolates
While there were only 9 publicly available Salmonella Mississippi isolates from New
Zealand, there were a large number of SNPs between these isolates and those from Australia
(Appendix Figure 3). There was also considerable heterogeneity within the Australian isolates,
with a maximum of 649 SNPs between 2 isolates.
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Comparatively, there was much less variability among the Australian and New Zealand
Salmonella Typhimurium DT160 isolates (Appendix Figure 4).
Violin plots were made using Stata SE 14, with the vioplot package.
Selected Risk Factors for Salmonella Mississippi and Salmonella Typhimurium DT160
We compared data on risk factors for Salmonella Mississippi and Salmonella
Typhimurium DT160 cases in the week before the onset of illness using a 2-sample test of
proportions (Appendix Table 4).
Salmonella Typhimurium DT160 Australian Case Animal Contact
Of the 88% (36/41) of Australian Salmonella Typhimurium DT160 cases that reported
direct animal contact, animals included dogs (n = 27), cats (n = 18), chickens (n = 12), birds (n =
6), possum (n = 3), wallabies or kangaroos (n = 3), horses (n = 3), sheep (n = 2), rabbits (n = 2),
and 1 each of cows, goats, pigs, fish, guinea pigs, deer, bandicoot, and worms and snails.
References
1. Wick RR, Judd LM, Gorrie CL, Holt KE. Unicycler: resolving bacterial genome assemblies from short
and long sequencing reads. PLOS Comput Biol. 2017;13:e1005595. PubMed
https://doi.org/10.1371/journal.pcbi.1005595
2. Gupta R, Schmidtke A, Sabol A, Castillo D, Ribot E, Trees E. Salmonella enterica subsp. enterica
serovar Mississippi str. 2010K–1406, whole genome shotgun sequencing project. Acession
ALPQ000000001. GenBank. 2012 [cited 2018 Apr 23].
https://www.ncbi.nlm.nih.gov/nuccore/ALPQ00000000.1
3. Grange ZL, Biggs PJ, Rose SP, Gartrell BD, Nelson NJ, French NP. Genomic epidemiology and
management of Salmonella in island ecosystems used for takahe conservation. Microb Ecol.
2017;74:735–44. PubMed https://doi.org/10.1007/s00248-017-0959-1
4. den Bakker HC, Moreno Switt AI, Govoni G, Cummings CA, Ranieri ML, Degoricija L, et al. Genome
sequencing reveals diversification of virulence factor content and possible host adaptation in
distinct subpopulations of Salmonella enterica. BMC Genomics. 2011;12:425. PubMed
https://doi.org/10.1186/1471-2164-12-425
188
Appendix Table 1. Sex and median age of cases with sampled isolates and all Salmonella Mississippi isolates, Tasmania, 2011–2015, MDU PHL, sample 1Variable All isolates Sampled isolates% M 47 64Median age, y 45 50
Appendix Table 2. Sex and median age of cases with sampled isolates and all Salmonella Mississippi isolates, Tasmania, 2011–2015, MDU PHL, sample 2Variable All isolates Selected isolates% M 47 53Median age, y 45 42
Appendix Table 3. Sex and median age of cases with sampled isolates and all Salmonella Mississippi isolates, mainland Australia2011–2015, MDU PHLVariable All isolates Selected isolates% M 40 38Median age, y 45 54
Appendix Table 4. Salmonella Mississippi and Salmonella Typhimurium DT160 cases who answered yes to risk factor questions ofthose who answered the question, Australia
VariableSalmonella Mississippi,
no. (%)Salmonella Typhimurium DT160,
no. (%) p valueBushwalking 2/25 (8) 3/40 (7.5) 0.94Camping 2/26 (8) 0/40 (0) 0.07Gardening 4/25 (16) 9/41 (22) 0.56Swimming 4/25 (16) 7/39 (18) 0.84Drinking from an untreated raw water source 14/23 (61) 12/30 (40)* 0.1Animal contact 19/28 (68) 36/41 (88) 0.04*2/12 (17%) reported boiling their water before drinking.
Appendix Figure 1. Age distribution of all Salmonella Mississippi cases with isolates, Tasmania,
Australia, 2011–2015, Microbiological Diagnostic Unit Public Health Laboratory, sample 2.
189
Appendix Figure 2. Month of isolation of all Salmonella Mississippi cases with isolates, Tasmania,
Australia, 2011–2015, Microbiological Diagnostic Unit Public Health Laboratory, sample 2.
Appendix Figure 3. Violin plot of single nucleotide polymorphisms within Australian and New Zealand
clades and between them, Salmonella Mississippi, 2008–2015.
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