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Health inequalities in heart failure: A population-based study of 20-year trends in
cause-specific outcomes by gender, socioeconomic status and location of care
Lawson CA, Zaccardi F, Squire I, Ling S, Davies M, Lam C, Mamas M, Khunti K, Kadam
UT
Claire A Lawsona – PhD, Lecturer & Wellcome Trust FellowFrancesco Zaccardia –PhD, Clinical Research FellowIain Squireb – MD; Professor of Cardiovascular MedicineSuping Linga – PhD, EpidemiologistMelanie J Daviesa – MD; Professor of Diabetes MedicineCarolyn SP Lamc – PhD, Professor of Duke-NUS Cardiovascular Academic Clinical Program Mamas Mamasd – PhD, Professor of CardiologyKamlesh Khuntia – PhD, Professor of Primary Care Diabetes & Vascular MedicineUmesh T Kadama – PhD, Professor of Primary Care & Public Health Research
a. Leicester Diabetes Centre, Leicester University, Leicestershire, UKb. NIHR Leicester BRC, Cardiovascular Research Centre, Glenfield General
Hospital, Leicester University, Leicestershire, UKc. National Heart Centre Singapore, Duke-NUS, University Medical Centre
Groningen, The George Institute for Global Healthd. Keele Cardiovascular Research Group, Centre for Prognosis Research, Keele
University, Staffordshire, UK
Word count: Abstract 299; Text 3895
3 Figures; 4 tables
Corresponding author:
Dr C. A. Lawson Diabetes Research CentreUniversity of LeicesterLeicester, LeicestershireLE5 4PW, England, UKEmail: [email protected]: +44 (0) 4782 709 590
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Abstract:
Background: Heart failure (HF) is a global pandemic but contemporary trends in cause-
specific outcomes among different population groups are unknown.
Methods: In a retrospective cohort of incident HF patients between 1998 and 2017
(N=88,416, mean age 78-years, 49% female, median follow-up 2.4 years), cause-specific
hospitalisation and mortality were investigated.
Findings: First-year age-adjusted hospitalisation rate increases were: all-cause 28% from
97.1 (95% CI 94.3,99.9) to 124.2 (120.9,127.5); HF-specific 28% from 17·2 (16·2,18·2) to
22·1 (20·9,23·2) and non-cardiovascular 42% from 59·2 (57·2,61·2) to 83·9 (81·3,86·5) per
100 person-years. Over 70% of all admissions were for non-cardiovascular causes and annual
rate increases were faster for women (+3·9%; 2·8,4·9) than men (+1·4%; 0·6,2·1)
(P<0·0001) and for HF patients diagnosed in hospital (+2.4%; 1·4,3.3) than in the community
(+1·2%; 0·3,2·2). Annual increases for HF hospitalisations were 2·6% (1·9,3·4) for women
and 1·6% (0·6,2·6) for the most deprived, compared to stable rates in men and the most
affluent. Overall, the most deprived (adjusted Incident Rate Ratio 1·20; 1·17,1·24) and
hospital-diagnosed groups (aIRR 1·52; 1·49,1·55) had significantly higher risk of all-cause
admission, but women had significantly lower risk than men (aIRR 0·91; 0·90,0·92).
All-cause first-year age-adjusted mortality rate reduction was 6% from 24·5 (23·4,39·2) to
23·0 (22·0,24·1). Annual rate reductions were -1·4% (-2·3, -0·5) in men but stable for
women and -2·7% (-3·2, -2·2) for the community group compared to -1·1% (-1·8, -0·4) in
the hospital-diagnosed group (p<0·0001). Overall, the most deprived (adjusted Hazard Ratio
1·17;1·14,1·21) and hospital-diagnosed groups (aHR 1·46;1·43,1·48) had significantly higher
risk of all-cause mortality, but women had significantly lower risk than men (aHR
0·85;0·83,0·86).
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Interpretation: Tailored management strategies and specialist HF care are needed to address
persisting and increasing inequalities for men, the most deprived and for HF patients
diagnosed in hospital and to address the worrying trends in women.
Funding: Wellcome-Trust
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Research in context
Evidence before this study
Heart failure is a global pandemic affecting 23 million people worldwide and associated with
adverse clinical outcomes (high hospitalisation burden, costs and mortality). We searched
PubMed from 2000 onwards, for observational studies reporting outcome trends in HF. We
used the term ‘heart failure’ in different combinations with ‘surviv*’, ‘rate*’, ‘outcome*’,
‘mortality’, ‘death*’, ‘hospital*’, ‘prognos*’ and ‘trend*’. We reviewed the full text of
relevant articles to assess appropriateness for inclusion. Most studies were from the USA and
were focused on specific care settings (hospital or community) that are unable to ascertain HF
incidence date accurately, or on single communities, which may not reflect the general
population. No studies had reported on cause-specific outcome trends in a national sample of
incident HF patients, regardless of location of care, among different population groups.
Added value of this study
By linking national general practice, hospital and death data, we were able to report outcome
burden following newly diagnosed heart failure and make group comparisons. We found that
hospitalisation rates are increasing and, whilst mortality has improved slightly over twenty
years, risk is higher than previously reported in non-incident cohorts. Furthermore, there were
inequities in outcomes among different HF population groups, some of which persisted or
worsened over time. Risks of all outcomes were significantly higher in the older compared to
younger age groups, for men compared to women, the most deprived compared to the most
affluent and for patients who were first diagnosed with their heart failure in hospital
compared to in the community. We also observed worrying trends for women with HF, with
worsening outcomes in recent years. By investigating cause specific outcomes, we were able
to show that these disparities likely reflect the growing burden of non-cardiovascular
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comorbidities in HF patients, requiring contemporary prevention and management
approaches.
Implications of all the available evidence
Heart failure presents a major and persistent public health challenge. Diverging outcome
trends among groups, alongside increasing non-cardiovascular outcomes, means that
disparities according to age, gender, socioeconomic status and location of care are set to
increase. Tailored management strategies that include access to specialist HF teams together
with non-cardiovascular and social interventions are urgently required to address the growing
complexity of HF patients and reduce the inequitable outcomes of care.
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Introduction
Heart failure is a global pandemic affecting around twenty-three million people worldwide
including six million Americans,(1) over fifteen million Europeans and one million people in
the UK alone.(2,3) Despite improvements in HF therapies over the past two decades, mortality
risk remains high,(4) with inequalities reported among population groups according to factors
such as gender and socioeconomic status.(5-7) Hospitalisation burden is also high, accounting
for over two thirds of the estimated US$108bn spent on HF globally each year.(8)
Furthermore, the economic costs associated with HF are likely to increase exponentially over
the next decade due to a projected 46% increase in HF prevalence by 2030,(9) alongside rising
costs of healthcare in an ageing, multi-morbid population. Consequently, attempts to reduce
the significant social, health and economic burden of HF have become a top public health
priority.(10)
Prior epidemiological evidence in HF has predominantly focused on mortality in higher risk
hospitalisation cohorts,(11-13) lower risk primary care cohorts(14) or selected communities(5,6,15)
which may not represent the general HF population and limit the potential for group
comparisons. In order to develop tailored public health prevention approaches and to plan
health services effectively, contemporary population level data on emerging outcome trends
among different HF population groups are required. Information on cause-specific
hospitalisation rates in HF is particularly important to meet the projected rising demands.
Through linkage of primary care, hospital and death data we investigated differences in
cause-specific outcomes and trends among groups with incident HF according to gender,
socioeconomic status and location of care.
Methods
Study design and participants
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We used Clinical Practice Research Datalink (CPRD) and Hospital Episodes Statistics (HES)
databases, to identify an incident cohort of HF patients between 1st January 1998 and 31st July
2017. The CPRD is one of the largest longitudinal linked anonymised databases in the world
and contains approximately 7% of the UK general population, representative of sex and age.
It includes patient demographics, risk factors, symptoms, clinical diagnoses, investigations,
referrals and prescriptions and has been validated for epidemiological research.(16) HES
includes all National Health Service admissions in England. The Independent Scientific
Advisory Committee provided permission for data access (protocol 18_037R).
We included all patients aged ≥ 30 years with a first code for HF in their primary care or
hospital record during the 20-years. To ascertain HF diagnostic date accurately, patients were
only included if their CPRD and HES records were eligible for linkage and they had been
registered with a CPRD primary care practice for a minimum of 1-year prior to study entry.
We used updated, clinically validated HF CPRD codes(17) and primary ICD-10 discharge
codes (S1 and S2 Table). Where patients had codes in both records, the first was assigned as
the HF diagnosis date.
Procedures
Exposure group: Patients were categorised into groups defined by age (<70 years, 70-79
years, 80-89 years and ≥ 90 years), gender, socioeconomic status and location of care.
Socioeconomic status was based on the 2010 patient level Index of Multiple Deprivation
(IMD).(18) score which was ranked into quintiles (the most affluent group; quintile 1, to the
most deprived group; quintile 5). Location of care was defined by place of HF diagnosis
(community or hospital), based on the first HF code.
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Confounders: Risk factors, using the most recent value, included current smoking and alcohol
(yes or no), body mass index, systolic blood pressure, cholesterol, haemoglobin and estimated
glomerular filtration rate (eGFR) which .was calculated using the Chronic Kidney Disease
Epidemiology Collaboration formula.(19) Prescribed drugs including beta blocker,
angiotensin converting enzyme inhibitors, angiotensin II receptor blockers, aldosterone
receptor antagonists, aspirin and loop diuretics were identified by at least one prescription in
a 4-month time-window prior to HF diagnosis. Comorbidities were identified by at least one
Read or ICD-10 code in CPRD and HES respectively, at any time up to and including the HF
diagnosis date.
Outcomes: Hospitalisations included all non-elective admissions with at least one overnight
stay and occurring after but not including the HF index date. Overall hospitalisations during
follow-up were counted for each patient and further stratified by cause-specific admissions:
primary HF, other-cardiovascular and non-cardiovascular (non-CVD) admissions according
to the primary discharge code.
Date and cause of death was ascertained from linked Office of National Statistics mortality
records. We coded deaths as ‘cardiovascular’ where there was an ICD-10, chapter 9 code in
the primary position and ‘non-CVD’ for all remaining deaths.
For both outcomes follow-up was until death or study end (31st July 31st).
Statistical analysis
Descriptive statistics are presented as number (%) for dichotomous data, mean (standard
deviation) for continuous data and median (25th and 75th centiles) for skewed continuous data.
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Trend analyses were performed in the whole group and stratified by age groups, gender,
socioeconomic status (most affluent quintile, most deprived quintile) and location of care
(community; hospital). Given the higher risk of poor outcomes in the first year following HF
diagnosis, outcome rates were calculated separately for the first year (first-year rates) and for
the second-year onwards (subsequent-year rates). Additionally, due to the high risk of death
in the first month following HF diagnosis, first-year mortality rates were only calculated in
survivors of the first month. Rates were estimated at the mean population age using age-
adjusted negative binomial models. There were three trend measurements: (i) comparison of
outcomes rates between two 4-year time windows of HF diagnosis (at the start; 1998-2002
and the end; 2012-2015), (ii) average annual percentage change in outcome rates and (iii)
change in trends using Joinpoint Regression which is a statistical software that calculates
annual percentage rate change and tests whether any apparent change in trend is significant.
(20)
Difference in trends between population groups were investigated by fitting an interaction
term (group x HF diagnostic year) to the negative binomial models already containing age.
As interaction tests have low power, we also examined trends visually by plotting graphs of
outcome rates by year of HF diagnosis to aid interpretation.
For overall differences between groups we compared each older age group with the youngest
age group (<70 years; ref), females with males (reference), lower socioeconomic quintiles
(Q2-Q5) with the most affluent quintile (Q1; reference) and the hospital diagnosed group
with the community diagnosed group (reference). Differences in total and cause-specific
admission rates among groups were investigated using negative binomial models to estimate
incidence rate ratios (IRR) with 95% confidence intervals, adjusted for all covariates. For
time to mortality outcomes we used Royston-Parmer flexible parametric survival models to
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perform age-standardised survival predictions at 1, 3 and 5-years for the whole group and
population sub-groups by time-period of diagnosis. Next, age and calendar year standardised
survival curves (all-cause mortality) and cumulative incidence curves (cause specific
mortality) were plotted.(21) Finally, adjusted Hazard ratios (HR) with 95% confidence intervals
were estimated, comparing each sub-group with their respective reference group for all-cause
and cause-specific death.
All analyses were performed using Stata-MP 14. To account for missing data in the
multivariable models (S3 Table), multiple imputations using matching variables and full-
conditional specification were performed, using MI Impute command and results were
obtained using Rubin’s rules.(22) We performed a sensitivity analysis to assess complete case
analysis, removing those with missing values imputed.
Role of the funding source
The funder of the study had no role in study design, data collection, data analysis, data
interpretation, or writing of the report. The corresponding author had full access to all of the
data and the final responsibility to submit for publication
Results
There were 88,416 incident HF patients over the 20-year study time-period, mean age 78-
years, 43,461 (49%) were female and median follow-up was 2·4 years [0·5, 5·7] (Table 1, S1
Figure). Of the study population, 36,415 (41%) patients were first diagnosed with HF in
hospital, a proportion that increased exponentially over time from 26% in 1998 to 74% in
2017 (S2 Figure).
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In the first year following HF diagnosis, 40% of patients had at least one and 20% had
multiple, hospitalisations. First-year hospitalisation rates increased by 28% from 97·1 (95%
CI 94·3,99·9) per 100 person-years during the earlier time-period (1998-2001) to 124·2 (95%
CI 120·9,127·5) during the later time-period (2012-2015), but rates began to plateau after
2005 (Table 2). The steepest growth in first-year rates was for people aged over 80 years
with rates for the younger two age groups remaining stable. Subsequent-year hospitalisation
rates were lower and remained stable overall, but with reducing rates for the youngest and
increasing rates for the oldest age groups (S4 Table).
HF was listed as the primary cause in 17% of hospitalisations occurring in the first year
following HF diagnosis and 10% of hospitalisations occurring in subsequent years. First-year
HF hospitalisation rates increased from 17·2 (16·2,18·2) to 22·1 (20·9, 23·2) per 100 person-
years, at an average increase of 1·8% per annum (pa) (Table 2), whilst subsequent-year rates
remained stable (S4 Table). This steady increase was in contrast to hospitalisations for other
CVD causes which reduced by 2·4% pa after 2005 (Figure 1). Non-CVD was the primary
diagnosis in 73% of all hospitalisations·, with first-year rates increasing from 59·2 (83·9,
86·5) to 83·9 (81·3, 86·5) per 100 person-years, an average increase of 2·6% pa (Table 2).
Subsequent year rates were also high and increased by 0·8% pa, reaching 64·0 (62·3, 65·8)
per 100 person-years during 2012-2015 (S4 Table).
During follow-up, 65,063 (74%) patients with HF died with 32,623 (50·1%) cardiovascular
and 32,440 (49·9%) non-CVD deaths. Between 1998-2001 and 2012-2015, the number of
people dying within one month of their HF diagnosis reduced from 14% to 11% (Table 3). In
those surviving their first month, age-adjusted first-year mortality rates reduced only slightly
from 24·5 (23·4, 25·7) to 23·0 (22·0, 24·1) per 100 person-years, but there were differences
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by age (Table 3). The youngest two age groups experienced mortality rate reductions whilst
the oldest groups had a significant increase in mortality rates. In the group aged > 90-years,
rates increased by 20%, reaching 69·6 (63·2, 76·0) per 100 person-years (Table 3, Figure 2).
Subsequent year mortality rates were lower and reduced by 16% over time, reaching 14·7
(14·3, 15·2) per 100 person-years (Table 3). Age-standardised mortality risk reduced
between the two time-periods; 1-year (32% vs 29%), 3-year (50% vs 46%) and 5-year risk
(63% vs 59%) (S5 Table).
Outcomes by gender: During 1998-2002, first-year and subsequent-year age-adjusted rates of
any and cause-specific hospitalisations were higher for men than women. However, by 2012-
2015, first-year rates for all-cause hospitalisations were significantly higher in women
(129·7; 124·7, 134·7) compared to men (119·1; 114·8, 123·5) per 100 person-years,
explained by increasing rates for women, compared to stable rates in men (Table 2, Figure
1). Women also had over twice the increase in first-year non-CVD hospitalisation rates (3·9%
pa) compared to men (1.4% pa). Similar patterns were found for subsequent-year rates. After
full co-variate adjustment, women had lower incidence rate of all cause-specific
hospitalisation types than men, with the largest reduction for CVD hospitalisations (IRR
0·85; 0·83, 0·88) (Table 4). However, when stratified by year of diagnosis, these risk
differences diminished and became statistically insignificant in later years (not shown).
In 1998-2001, first-year mortality rates per 100 person-years were higher for men (29·2;
27·4, 31·0) than women (20·7; 19·5, 22·0) but the gap diminished by 2012-2015 with rates of
23·5 (22·1, 24·9) for men and 22·0 (20·7, 23·4) for women. This was due to with a 2·6% pa
reduction in rates for men prior to 2009 compared to stable rates in women (Table 3, Figure
2). Subsequent-year rates reduced at twice the rate in men (-2·2%; -2·5, -1·9 pa) than women
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(-0·8%; -1·1, -0·5 pa). Overall, age-standardised mortality risk at 1, 3 and 5 years was
approximately 3-4% higher in men than women which persisted over time (S5 Table) and
following full adjustment, women were at lower risk of all-cause deaths (HR 0·85; 95% CI
0·83,0·86), CVD deaths (HR 0·85; 95% CI 0·83, 0·88) and non-CVD deaths (HR 0·84; 95%
CI 0·82,0·87) compared to men (Table 4, S3 Figure). Again, after stratifying by year of
diagnosis (not shown), the difference between gender groups was attenuated, becoming
statistically insignificant by 2016.
Outcomes by socioeconomic status: In 1998-2002, first-year any cause hospitalisation rates
were significantly higher in the most deprived than the most affluent group. This difference
persisted over-time due to similar increasing rates in both groups (P=0·103) (Table 2, Figure
1) and subsequent-year rates showed a similar pattern. In the most recent time-period (2012-
2015), the biggest difference was for first-year non-CVD hospitalisations, with the figures for
most deprived of 101·7 (93·9, 109·5) per 100 person-years compared to 60·8 (58·1, 63·5) for
the most affluent (Table 2). In fully adjusted models, the most deprived compared to the
most affluent group had significantly higher risk of all-cause (IRR 1·20; 1·17, 1·24),
cardiovascular (IRR 1·18; 1·13, 1·19) and non-CVD hospitalisations (IRR 1·21; 1·22, 1·25).
Risk increased with quintiles of socioeconomic status from the highest (Q1) to the lowest
quintile (Q5) (Table 4).
In the most-recent time-period, first-year mortality rates per 100 person-years were higher in
the most deprived group (25·7; 22·9, 28·5) compared to the most affluent group (21·1; 19·1,
23·1) (Table 3, Figure 2). Age standardised mortality risk increased for each quintile of
socioeconomic status, from the most affluent to most deprived group. In the later time-period
risk ranged from 27% (Q1) to 32% (Q5) at 1-year, 43% to 50% at 3-years and 56 to 63% at
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5-years (S5 Table). Following full adjustment, the most deprived group remained at higher
risk of all-cause death (HR 1·17; 1·14, 1·21), CVD death (HR 1·18; 1·14, 1·23) and non-
CVD death (HR 1·17; 1·13, 1·22) than the most affluent group and age-standardised survival
reduced for each quintile of socioeconomic status (Table 4, S3 Figure).
Outcomes according to location of care: First-year hospitalisation rates for any cause (per
100 person-years) were significantly higher in the hospital-diagnosed than the community-
diagnosed group, with similar growth over time reaching 163·2 (157·7, 169·0) and 88·3
(84·9, 91·6) respectively by 2012-2015. Annual rates between the two groups began to
diverge after 2004 reducing at the same rate for the community group as they increased for
the hospital group (1% pa) (Table 2, Figure 1). The hospital group experienced a consistent
2·4 % pa increase in first-year non-CVD hospitalisations, whilst rates did not increase for the
community group after 2004.· When adjusted for all covariates the hospital group had
significantly higher risk of cardiovascular (incidence rate ratio [IRR] 1·77; 1·72, 1·82) and
non-CVD (IRR 1·40; 1·37, 1·43) hospitalisations than the community group (Table 4).
First-year mortality rates in the hospital group (34·3; 32·3, 36·2) were more than double the
rates in the community group (14·2; 13·2, 15·1) per 100 person-years and this gap widened
over time (p<0·0001). Age-adjusted mortality rates reduced in the community group (-2·7%;
-3·2, -2·2 pa) at twice the rate of the hospital group (-1·1%; -1·8,-0·4 pa) (Table 3, Figure
2). A similar trend was identified for subsequent-year rates (S4 Table).
During 2012-2015, age-standardised mortality risks remained significantly higher in the
hospital-diagnosed compared to community-diagnosed group: 1-year risk (34 vs 24%), 3-year
risk (53 vs 40%) and 5-year (66 vs 52%) (S5 Table). Overall, median survival time in the
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community group (4·2; 1·0, 9·5 years) was twice that of the hospital group (1·9; 0·2, 5·6)
(Table 4, S3 Figure). In the fully adjusted models, the hospital-diagnosed group had
significantly higher risk of CVD deaths (HR 1·55; 95% CI 1·51, 1·59) and non-CVD deaths
(HR 1·37; 95% CI 1·34, 1·40) than the community group (Table 4).
For all groups, risk of cardiovascular death was higher than non-CVD deaths for the first few
years following HF diagnosis but the two causes converged in later years with non-CVD
causes taking over at around 3-5 years (S4 Figure). Effects remained relatively stable
following full case analysis (S6 Table).
Discussion
Our study provides a comprehensive and contemporary assessment of outcomes in patients
with incident HF in community and specialist hospital settings. In a large, nationally
representative sample over 20 years, there were specific diverging trends and inequalities in
hospitalisations and mortality. Non-elective hospitalisation burden has increased, particularly
for non-CVD causes, which account for over two-thirds of all admissions. HF remains
associated with a high risk of death, with only minimal improvement in risk over the last 20
years. Inequalities and poor outcomes have persisted, particularly for the oldest age groups,
men, the most deprived and for patients diagnosed in hospital and new worrying trends for
women have emerged.
Mortality risk following HF diagnosis has reduced only minimally over the past two decades.
Whilst one and five-year mortality risk reduced by 3-4%, this small reduction is likely in part
to reflect advances in diagnostic technology to identify milder HF over this time. Despite the
risk reduction, our 1 and 5-year figures are similar or worse than those at the turn of the
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century in the Framingham (29% at one year) and Rochester (48% at five years) cohorts.(23, 24)
Hospital cohorts in the USA,(25) Scotland,(26) and recently in Demark(27) reported slightly
lower 1-year risk of 29%, 33% and 30% compared to the 34% risk in our hospital diagnosed
group. Similarly, community cohorts from UK(14) have recently reported 1-year risk of 24%
compared to the 27% overall 1-year risk in our community diagnosed group. Like most prior
HF epidemiological evidence from ‘hospital only’ or ‘primary care only’ cohorts, these
cohorts were not able to ascertain HF diagnosis date. By linking community and hospital
records we were able to identify incident HF, which likely accounts for the higher mortality
risk in our study and indicates that the true risk burden for HF patients may be higher than
previously reported. The persisting high risk in HF possibly reflects the ageing multi-morbid
population, alongside a survival plateau in the era of effective, evidence-based treatment for
HF (selective beta-blockers and angiotensin converting enzyme inhibitors). The rise in the
number of non-CVD hospitalisations as well as the 50% deaths for non-CVD causes would
support this hypothesis.
We observed a new and important trend of increasing HF hospitalisations. Prior evidence on
cause-specific trends grouped HF admissions with cardiovascular admissions, reporting
stable or reducing rates over time.(5) By partitioning out HF from other-cardiovascular
admissions we identified a new trend, not previously reported. This is particularly important
given the growth of day case diuretic units that should reduce the number of acute HF
patients needing hospitalisation and meaning that our findings may underestimate the
worsening acute HF problem. Increased HF hospitalisations were particularly pronounced in
women and possibly indicates later presentation of more severe HF in older multi-morbid
patients. Other potential triggers may be the lack of evidenced based therapies for HF with
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preserved ejection fraction which is increasing in prevalence(28) or improved survival of more
severe HF patients with contemporary HF therapies.
Hospital-diagnosed HF patients had significantly worse outcome rates over time compared to
the community group, a finding shared by previous reports.(29,30) Our findings reveal a
worrying exponential increase in these patients reaching 79% of the HF population by 2017.
Furthermore, our study showed that the steeply rising burden of non-CVD hospitalisations
were predominantly focused to the hospital-diagnosed group. Death rates were also
significantly higher for the hospital-diagnosed group with slower rates of decline than in the
community group. Delay in diagnosis, higher comorbidity burden and lower prescribing of
first-line preventive medications in community care, leading to more severe HF at the point
of diagnosis, may part explain the worse prognosis in this group. Recent developments
suggests that growth of dedicated HF specialists has better outcomes for hospitalised patients
(UK National Heart Failure Audit)(31) and recent policy recommends that all patients with HF
have access to a multidisciplinary team.(32) It is also important to remember that “evidence-
based” treatments in HF are relevant only to those patients with reduced ejection fraction, and
some of the apparent under-use of these treatments may be explained by the lack of evidence
for the use of these treatments in HFpEF. A recent report shows that around half of these
hospital diagnosed patients present earlier to their primary care with HF symptoms,(33)
demonstrating an urgent need for specialist support for earlier diagnosis.
Prior HF studies have shown worse outcomes for men than women.(6,34) Our findings show
that steeper increases in HF and non-CVD hospitalisation rates for women as well as slower
reduction in mortality rates in women compared to men has resulted in .similar outcomes
between the genders in recent years, a finding also reported recently in Denmark and
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Ontario(27,29) These trends likely reflect the increasing prevalence of non-CVD comorbidities
in women. However, the attenuation of gender difference over time, even after taking account
of comorbidities, as well as greater increasing rate of HF hospitalisations over time in
women, suggest worsening HF severity or lack of effective HF therapies in women compared
to men. These unfavourable trends in women may also relate to the increasing prevalence of
HF with preserved ejection fraction (HFpEF) in women (for which there is still, to date, no
proven therapy to improve outcomes).(12,35)
The most deprived HF group compared to the most affluent group had consistently poor
outcomes, with 20% higher risk even after adjustment, an inequality that has persisted over
the last 20 years. Previously, deprivation status has not been associated with cause-specific
hospitalisations,(7) but our study highlights a new finding of increased risk across all cause-
specific outcomes in the most deprived HF patients. Whilst higher burden of comorbidities
and worse lifestyle risk factors may partly explain this increased risk, the persisting
difference following full adjustment for these factors suggests other social and healthcare
factors may be at play.(36) Potential delays in health seeking behaviour,(37) with higher severity
of comorbidities and HF at the point of diagnosis, may be one explanation and points to the
preventable nature of HF. Lower prevalence of cancer in the most deprived group opposes
the trends found for other comorbidities, but is perhaps unsurprising considering the
persistent socioeconomic inequalities in cancer survival.(38)
To our knowledge, this is the largest incident HF study to report trends in cause-specific
hospitalisations and mortality in general population groups. .By linking large, nationally
representative databases, we were able to ascertain the incident date of HF and follow
patients for up to 20 years for cause-specific hospitalisations and death. However, the use of
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routinely collected data means HF diagnosis can be subject to misclassification and
measurement error, which may change over time. Diagnosis of HF in the community is
clinically defined and we cannot rule out that the lower risk in the community group may in
part be due to misclassification. However, in the UK, HF diagnosis has been enhanced by the
introduction of echocardiography as part of performance incentives(39) and national HF audits
and HF diagnoses have been shown to have high precision in CPRD.(17) The outcomes
measured in the study are also dependent on HF severity or type but routine data did not
provide echocardiographic data or specific HF phenotypes. To account for severity, a range
of comorbidity and medications were included in our analyses, but further investigation on
specific HF phenotypes with outcomes is required. Accuracy of clinical recording and
diagnoses within the CPRD have been found to be valid for a range of morbidities(16) and we
also used primary ICD codes for cause-specific outcomes and clinically validated code sets
which have high precision.(17) Changes in diagnostic procedures over time, such as more
advanced echocardiography to detect milder forms of HF, may have influenced our findings
and be partly responsible for the small reduction in mortality risk over time. This bias would
only serve to temper the overall mortality risk in the later time-period as well as suppress
increasing hospitalisation rates, meaning that the overall burden of HF could be even higher
than reported.
Conclusions
Population inequalities in outcomes of HF present a major and persistent public health
challenge. Diverging trends among groups, alongside increasing non-CVD outcomes, means
that disparities according to age, gender, socioeconomic status and location of care are set to
increase. Tailored management strategies that include access to specialist HF teams together
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with non-CVD and social interventions are urgently required to address the growing
complexity of HF patients and reduce the inequitable outcomes of care.
Acknowledgements
The research was supported by Leicester-Wellcome Trust ISSF Fellowship [Reference
204801/Z/16/Z]. FZ is funded with an unrestricted educational grant from the NIHR
CLAHRC East Midlands to the University of Leicester.
The study sponsors had no role in the design and conduct of the study; collection,
management, analysis, and interpretation of the data; preparation, review, or approval of the
manuscript; and decision to submit the manuscript for publication. The views and opinions
expressed therein are those of the authors and do not necessarily reflect those of the NIHR
(UK) or Wellcome Trust.
Data
CL had full access to all the data in the study and takes responsibility for the integrity of the
data and the accuracy of the data analysis. This study is based in part on data from the
Clinical Practice Research Datalink obtained under licence from the UK Medicines and
Healthcare products Regulatory Agency. However, the interpretation and conclusions
contained in this report are those of the author/s alone. Data access is through permissions
from CPRD only.
Author contributions
CAL: conception, design, acquisition, analysis, interpretation of data, writing; FZ: design,
analysis, interpretation, critical revision; IS: design, interpretation, critical revision; SL:
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acquisition of data, interpretation, critical revision; MD: interpretation, critical revision; CL:
figures, interpretation, critical revision; MM: design, interpretation, critical revision; KK:
conception, design, acquisition, interpretation, critical revision; UK: conception, design,
analysis, interpretation of data, writing, critical revision
Declarations of Interest
Dr. Khunti reports personal fees from Amgen , personal fees from Astrazeneca, personal fees
from Bayer, personal fees from NAPP, personal fees from Lilly , personal fees from Merck
Sharp & Dohme , personal fees from Novartis, personal fees from Novo Nordisk , personal
fees from Roche, personal fees from Berlin-Chemie AG / Menarini Group, personal fees
from Sanofi-Aventis , personal fees from Servier, personal fees from Boehringer Ingelheim,
grants from Pfizer , grants from Boehringer Ingelheim, grants from AstraZeneca, grants from
Novartis, grants from Novo Nordisk, grants from Sanofi-Aventis, grants from Lilly, grants
from Merck Sharp & Dohme, grants from Servier, outside the submitted work; .
MJD has acted as consultant, advisory board member and speaker for Novo Nordisk, Sanofi–
Aventis, Lilly, Merck Sharp & Dohme, Boehringer Ingelheim, AstraZeneca and Janssen, an
advisory board member for Servier and as a speaker for Mitsubishi Tanabe Pharma
Corporation and Takeda Pharmaceuticals International Inc. She has received grants in support
of investigator and investigator initiated trials from Novo Nordisk, Sanofi–Aventis, Lilly,
Boehringer Ingelheim and Janssen.
All other authors have reported that they have no relationships relevant to the contents of this
paper to disclose.
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Table 1 Patient characteristics by gender, socio-economic status and location of care
Gender Socioeconomic status Location of care
CharacteristicsAll Men Women Q1 (most affluent) Q2 Q3 Q4 Q5 (most deprived) Community Hospital
(N=88,416) (N=44,955) (N=43,461) (N=16,481) (N=20,468) (N=18,910) (N=17,542) (N=14,861) (N=52,001) (N=36,415)
Age in years 77.8 (11.3) 75.3 (11.5) 80.3 (10.5) 79.0 (10.8) 78.7 (10.8) 78.2 (11.2) 76.9 (11.5) 75.6 (12.0) 76.9 (11.2) 79.0 (11.4)
<70 years 18168 (21) 12,178 (27) 5,990 (14) 2,884 (17) 3,659 (18) 3,664 (19) 3984 (23) 3953 (27) 11,627 (22) 6,541 (18)
70 to 79 years 25878 (29) 14,379 (32) 11,499 (26) 4,638 (28) 5,804 (28) 5,416 (29) 5336 (30) 4653 (31) 16,357 (31) 9,521 (26)
80 to 89 years 33152 (37) 14,956 (33) 18,196 (42) 6,542 (40) 8,104 (40) 7,310 (39) 6287 (36) 4837 (33) 18,697 (36) 14,455 (40)
90 years and over 1 1218 (13) 3,442 (8) 7,776 (18) 2,417 (15) 2,901 (14) 2,520 (13) 1935 (11) 1418 (10) 5,320 (10) 5,898 (16)
Female 43,461 (49) - - 7,804 (47) 9,889 (48) 9,258 (49) 8879 (51) 7552 (51) 24,700 (47) 18,761 (52)
Most affluent group 16,481 (19) 8,677 (19) 7,804 (18) - - - - - 10,011 (19) 6,470 (18)
Most deprived group 14,861 (17) 7,309 (16) 7,552 (17) - - - - - 8,463 (16) 6,398 (18)
Hospital diagnosis 36,415 (41) 17,654 (39) 18,761 (43) 6,470 (39) 8,384 (41) 7,662 (41) 7441 (42) 6398 (43) - -
Beta blocker 26,627 (30) 14,222 (32) 12,405 (29) 5,322 (32) 6,225 (30) 5,619 (30) 5224 (30) 4209 (28) 17,134 (33) 9,493 (26)
ACE inhibitor 33,083 (37) 18,350 (41) 14,733 (34) 6,040 (37) 7,717 (38) 7,054 (37) 6633 (38) 5596 (38) 21,978 (42) 11,105 (31)
ARB 9,166 (10) 4,354 (10) 4,812 (11) 2,009 (12) 2,171 (11) 1,905 (10) 1736 (10) 1332 (9) 5,541 (11) 3,625 (10)
ACE or ARB 40,983 (46) 22,031 (49) 18,952 (44) 7,795 (47) 9,567 (47) 8,715 (46) 8129 (46) 6723 (45) 26,689 (51) 14,294 (39)
AA 5,767 (7) 3,108 (7) 2,659 (6) 1,154 (7) 1,348 (7) 1,200 (6) 1148 (7) 908 (6) 3,432 (7) 2,335 (6)
Aspirin 33,908 (38) 18,697 (42) 15,211 (35) 6,068 (37) 7,719 (38) 7,303 (39) 6855 (39) 5911 (40) 21,404 (41) 12,504 (34)
Diuretic (loop) 43,332 (49) 21,412 (48) 21,920 (50) 7,987 (48) 10,113 (49) 9,274 (49) 8568 (49) 7307 (49) 28,139 (54) 15,193 (42)
Comorbidities
Number; mean (SD) 4.1 (2.0) 4.0 (2.0) 4.2 (2.1) 3.9 (2.0) 4.0 (2.0) 4.1 (2.0) 4.2 (2.1) 4.2 (2.1) 3.7 (2.0) 4.6 (2.1)
<2 8,634 (10) 4,760 (11) 3,874 (9) 1,730 (10) 2,068 (10) 1860 (10) 1601 (9) 1,343 (9) 6,386 (12) 2,248 (6)
2 to 3 27,676 (31) 14,798 (33) 12,878 (30) 5,416 (33) 6,476 (32) 6041 (32) 5307 (30) 4,387 (30) 18,495 (36) 9,181 (25)
4 to 5 31,205 (35) 15,785 (35) 15,420 (35) 5,834 (35) 7,396 (36) 6566 (35) 6193 (35) 5,171 (35) 17,699 (34) 13,506 (37)
>5 20,901 (24) 9,612 (21) 11,289 (26) 3,501 (21) 4,528 (22) 4443 (23) 4441 (25) 3,960 (27) 9,421 (18) 11,480 (32)
26
IHD 43,983 (50) 25,111 (56) 18,872 (43) 7,979 (48) 9,891 (48) 9356 (49) 8919 (51) 7,779 (52) 24,165 (46) 19,818 (54)
MI 23,481 (27) 14,795 (33) 8,686 (20) 4,311 (26) 5,266 (26) 4984 (26) 4734 (27) 4,162 (28) 13,197 (25) 10,284 (28)
AF 34,884 (39) 17,909 (40) 16,975 (39) 6,795 (41) 8,361 (41) 7481 (40) 6715 (38) 5,483 (37) 17,332 (33) 17,552 (48)
Hypertension 56,908 (64) 27,768 (62) 29,140 (67) 10,603 (64) 13,135 (64) 12068 (64) 11416 (65) 9,614 (65) 30,915 (59) 25,993 (71)
Diabetes 21,565 (24) 11,872 (26) 9,693 (22) 3,439 (21) 4,745 (23) 4462 (24) 4688 (27) 4,202 (28) 10,675 (21) 10,890 (30)
Stroke 10,686 (12) 5,556 (12) 5,130 (12) 1,911 (12) 2,386 (12) 2316 (12) 2178 (12) 1,878 (13) 5,668 (11) 5,018 (14)
Anaemia 11,167 (13) 4,419 (10) 6,748 (16) 19,42 (12) 2,,488 (12) 2415 (13) 2272 (13) 2,027 (14) 5,318 (10) 5,849 (16)
Obesity 22,207 (25) 11,319 (25) 10,888 (25) 3,457 (21) 4,725 (23) 4706 (25) 4910 (28) 4,380 (29) 12,475 (24) 9,732 (27)
CKD 37,850 (56) 17,244 (49) 20,606 (63) 7,361 (56) 9,062 (57) 8198 (56) 7349 (56) 5,821 (54) 20,021 (53) 17,829 (60)
COPD 16,438 (19) 9,229 (21) 7,209 (17) 2,282 (14) 3,299 (16) 3276 (17) 3688 (21) 3,859 (26) 8,900 (17) 7,538 (21)
Asthma 16,512 (19) 7,911 (18) 8,601 (20) 2,726 (17) 3,631 (18) 3371 (18) 3450 (20) 3,313 (22) 9,488 (18) 7,024 (19)
Depression 20,060 (23) 7,997 (18) 12,063 (28) 3,392 (21) 4,310 (21) 4301 (23) 4273 (24) 3,754 (25) 11,461 (22) 8,599 (24)
Osteoarthritis 32,580 (37) 13,753 (31) 18,827 (43) 6,097 (37) 7,612 (37) 6985 (37) 6333 (36) 5,490 (37) 18,462 (36) 14,118 (39)
Cancer 20,500 (23) 10,733 (24) 9,767 (22) 4,227 (26) 5,121 (25) 4444 (24) 3773 (22) 2,900 (20) 11,360 (22) 9,140 (25)
Dementia 3,993 (5) 1,502 (3) 2,491 (6) 7,28 (4) 9,35 (5) 896 (5) 790 (5) 633 (4) 1,927 (4) 2,066 (6)
Smoking 17,408 (21) 9,967 (23) 7,441 (18) 2,553 (16) 3,619 (19) 3554 (20) 3838 (23) 3,811 (27) 11,101 (23) 6,307 (18)
Alcohol 53,789 (71) 31,526 (79) 22,263 (61) 10,890 (77) 12,894 (74) 11503 (71) 10175 (67) 8,245 (64) 32,266 (73) 21,523 (68)
BMI (kg/m2) 26.8 (23.6, 30.8) 27.0 (24.1, 30.6) 26.6 (22.9, 31.2) 26.3 (23.4, 29.8) 26.6 (23.5, 30.4) 26.8 (23.6, 30.8) 27.2 (23.8, 31.4) 27.4 (23.8, 31.8) 26.8 (23.6, 30.6) 26.9 (23.6, 31.2)
Systolic BP (mm/Hg) 137.9 (21.7) 135.7 (20.9) 140.2 (22.2) 137.3 (21.2) 138.2 (21.7) 138.0 (22.0) 137.8 (21.8) 138.2 (21.6) 138.8 (21.8) 136.7 (21.5)
Cholesterol (mmol/L) 4.5 (3.8, 5.4) 4.3 (3.6, 5.1) 4.8 (4.1, 5.7) 4.5 (3.8, 5.4) 4.5 (3.8, 5.4) 4.6 (3.8, 5.4) 4.5 (3.8, 5.4) 4.5 (3.7, 5.3) 4.6 (3.9, 5.5) 4.4 (3.7, 5.3)
Haemoglobin (g/dL) 13.0 (1.9) 13.4 (2.0) 12.5 (1.7) 13.0 (1.9) 13.0 (1.9) 12.9 (1.9) 12.9 (1.9) 13.0 (1.9) 13.1 (1.8) 12.7 (1.9)
eGFR (ml/min/m2) 57.5 (20.9) 60.3 (21.4) 54.5 (19.9) 57.2 (20.1) 56.9 (20.4) 57.2 (20.6) 57.8 (21.2) 59.0 (22.4) 59.2 (20.3) 55.4 (21.4)
Data are reported as number of patients (%) or mean with standard deviation or median with 25th and 75th centiles. Q, quintile; ACE, angiotensin-converting enzyme; ARB, angiotensin receptor blocker; AA, aldosterone antagonist (spironolactone or eplerenone)· IHD, ischaemic heart disease; MI, myocardial infarction; AF, atrial fibrillation; CKD, chronic kidney disease; COPD, chronic obstructive pulmonary disease; BMI, body mass index; BP, blood pressure; eGFR, estimated glomerular filtration rate
27
650
Table 2 Predicted rates of admissions during the first year following HF diagnosis by population groups and calendar year
Predicted rateper 100 person-years (95% CI)
Relative diff. (%)a
PInteractionb
Average annual percent change per year (95% CI)c
Slope change: annual percent change before and after trend change (95% CI)d
1998-2001 2012-2015 Before Break After
All admissions
All 97·1 (94·3, 99·9) 124·2 (120·9, 127·5) 28 1·8 (1·2, 2·4) 3·7 (2·4, 5·2) 2005 0·4 (-0·2, 1·1)
<70 years 94·1 (88·2, 100·0) 89·0 (83·9, 94·0) -5 Ref -0·2 (-1·2, 0·8) -0·2 (-1·2, 0·8) N/A -0·2 (-1·2, 0·8)
70 to 79 years 91·9 (87·4, 96·3) 107·8 (102·3, 113·3) 17 <0·0001 0·9 (-0·1, 2·0) 3·1 (0·8, 5·4) 2005 -0·6 (-1·7, 0·6)
80 to 89 years 98·4 (93·6, 103·2) 144·6 (138·3, 150·8) 47 <0·0001 3·0 (2·4, 3·7) 6·3 (4·5, 8·1) 2004 1·3 (0·8, 1·8)
90 years and over 102·0 (92·1, 111·9) 174·1 (161·6, 186·7) 71 <0·0001 4·4 (2·7, 6·2) 10·9 (5·8, 16·3) 2004 1·1 (-0·2, 2·3)
Men 109·9 (105·4, 114·4) 119·1 (114·8, 123·5) 8 Ref 0·5 (-0·1, 1·0) 0·5 (-0·1, 1·0) N/A 0·5 (-0·1, 1·0)
Women 85·7 (82·3, 89·2) 129·7 (124·7, 134·7) 51 <0·0001 3·0 (2·1, 3·9) 6·0 (4·3, 7·7) 2006 0·4 (-0·7, 1·5)
Most affluent (Q1) 85·9 (79·8, 92·1) 109·7 (103·1, 116·3) 28 Ref 1·5 (0·0, 3·1) 4·0 (0·0, 8·2) 2004 0·2 (-1·1, 1·5)
Most deprived (Q5) 113·2 (105·8, 120·6) 145·3 (135·6, 155·1) 28 0·103 1·9 (0·9, 2·9) 1·9 (0·9, 2·9) N/A 1·9 (0·9, 2·9)
Community diagnosis 80·0 (77·3, 82·7) 88·3 (84·9, 91·6) 10 Ref 0·7 (-0·2, 1·6) 4·6 (2·2, 6·9) 2004 -1·3 (-2·1, -0·5)
Hospital diagnosis 145·0 (137·6, 152·5) 163·2 (157·3, 169·0) 13 0·058 0·9 (0·3, 1·5) 0·9 (0·3, 1·5) N/A 0·9 (0·3, 1·5)
HF admissions
All 17·2 (16·2, 18·2) 22·1 (20·9, 23·2) 28 1·8 (0·7, 2·9) 0·8 (-0·1, 1·7) 2011 5·2 (0·7, 9·9)
<70 14·5 (12·6, 16·3) 14·1 (12·5, 15·7) -3 Ref -0·5 (-2·7, 1·9) -6·5 (-10·1, -2·8) 2015 5·3 (1·7, 8·9)
70 to 79 16·4 (14·9, 17·9) 18·1 (16·3, 20·0) 10 0·761 0·1 (-0·9, 1·0) 0·1 (-0·9, 1·0) N/A 0·1 (-0·9, 1·0)
80 to 89 18·8 (17·1, 20·6) 26·9 (24·7, 29·1) 43 <0·0001 2·4 (1·7, 3·2) 2·4 (1·7, 3·2) N/A 2·4 (1·7, 3·2)
>90 17·8 (14·4, 21·2) 35·2 (30·4, 39·9) 98 <0·0001 3·7 (1·4, 6·0) 3·7 (1·4, 6·0) N/A 3·7 (1·4, 6·0)
Men 20·3 (18·7, 21·9) 22·4 (20·8, 24·1) 10 Ref 0·6 (-0·9, 2·1) -1·9 (-3·4, -0·4) 2009 5·3 (1·5, 9·3)
Women 14·6 (13·4, 15·8) 21·6 (20·0, 23·3) 48 <0·0001 2·6 (1·9, 3·4) 2·6 (1·9, 3·4) N/A 2·6 (1·9, 3·4)
Most affluent 15·1 (13·0, 17·3) 19·1 (16·9, 21·3) 26 Ref 1·2 (-0·3, 2·8) 1·2 (-0·3, 2·8) N/A 1·2 (-0·3, 2·8)
28
Most deprived 20·5 (18·0, 23·1) 26·2 (22·9, 29·5) 28 0·597 1·6 (0·6, 2·6) 1·6 (0·6, 2·6) N/A 1·6 (0·6, 2·6)
Community diagnosis 11·3 (10·5, 12·1) 12·3 (11·3, 13·2) 9 Ref 0·2 9-0·9, 1·3) 0·2 9-0·9, 1·3) N/A 0·2 9-0·9, 1·3)
Hospital diagnosis 35·5 (32·2, 38·7) 32·9 (30·8, 35·1) -7 0·403 -1·6 (-3·7, 0·6) -8·5 (-14·4, -2·1) 2003 1·4 (-0·5, 3·4)
Other CVD admissions
All 20·3 (19·3, 21·3) 22·5 (21·4, 23·5) 11 0·7 (-0·4, 1·8) 5·3 (2·9, 7·9) 2005 -2·4 (-3·7, -1·1)
<70 23·0 (20·2, 25·9) 17·8 (15·6, 20·1) -23 Ref -1·7 (-2·6, -0·7) -1·7 (-2·6, -0·7) N/A -1·7 (-2·6, -0·7)
70 to 79 19·9 (18·3, 21·5) 21·7 (19·8, 23·6) 9 0·003 0·0 (-2·1, 2·2) 4·5 (-0·2, 9·3) 2005 -3·0 (-5·5, -0·4)
80 to 89 19·0 (17·3, 20·8) 24·7 (22·6, 26·8) 30 <0·0001 2·4 (1·2, 3·7) 10·3 (6·7, 14·1) 2004 -1·6 (-2·6, 0·6)
>90 17·1 (13·6, 20·6) 27·9 (23·7, 32·2) 63 <0·0001 3·3 (-0·1, 6·8) 9·5 (3·7, 15·7) 2007 -3·4 (-7·9, 1·4)
Men 22·6 (21·1, 24·2) 21·9 (20·5, 23·3) -3 Ref -0·1 (-1·8, 1·6) 5·5 (1·1, 10·1) 2004 -3·0 (-4·6, -1·4)
Women 18·2 (16·9, 19·4) 23·1 (21·6, 24·7) 27 <0·0001 1·8 (0·4, 3·2) 6·7 (3·6, 9·9) 2005 -1·5 (-3·0, -0·0)
ost affluent 18·6 (16·4, 20·9) 21·2 (19·0, 23·4) 14 Ref 0·8 (-0·8, 2·5) 7·2 (2·6, 12·0) 2004 -2·5 (-4·0, -0·9)
Most deprived 23·0 (20·5, 25·5) 23·6 (20·8, 26·3) 3 0·942 -0·4 (-2·8, 2·1) 2·9 (0·2, 5·7) 2008 -4·9 (-9·9, 0·3)
Community diagnosis 17·2 (16·2, 18·3) 18·4 (17·2, 19·7) 7 0·5 (-0·9, 1·9) 5·9 (2·9, 9·0) 2005 -3·2( -4·7, -1·5)
Hospital diagnosis 29·3 (26·7, 31·9) 27·1 (25·4, 28·8) -8 0·003 -0·5 (-1·7, 0·8) 3·2 (-0·0, 6·6) 2004 -2·5 (-3·7, -1·2)
Non CVD admissions
All 59·2 (57·2, 61·2) 83·9 (81·3, 86·5) 42 2·6 (1·9, 3·3) 4·2 (2·8, 5·6) 2006 1·2 (0·3, 2·1)
<70 57·1 (51·8, 62·5) 60·5 (55·0, 65·9) 6 Ref 0·6 (-0·9, 2·2) 0·6 (-0·9, 2·2) N/A 0·6 (-0·9, 2·2)
70 to 79 55·7 (52·5, 58·9) 72·1 (67·8, 76·5) 29 0·006 1·9 (0·9, 2·8) 3·7 (1·6, 5·9) 2005 0·6 (-0·4, 1·6)
80 to 89 60·0 (56·3, 63·6) 98·7 (93·4, 104·0) 65 <0·0001 3·4 (2·8, 4·0) 3·4 (2·8, 4·0) N/A 3·4 (2·8, 4·0)
>90 66·7 (58·5, 74·8) 114·7 (103·6, 125·7) 72 <0·0001 4·2 (2·8, 5·6) 8·3 (4·9, 11·8) 2005 1·4 (0·1, 2·8)
Men 66·3 (63·1, 69·6) 79·4 (76·1, 82·8) 20 Ref 1·4 (0·6, 2·1) 1·4 (0·6, 2·1) N/A 1·4 (0·6, 2·1)
Women 52·9 (50·4, 55·5) 88·9 (84·9, 92·8) 68 <0·0001 3·9 (2·8, 4·9) 7·1 (5·1, 9·3) 2006 1·0 (-0·2, 2·3)
Most affluent (Q1) 50·9 (46·6, 55·2) 73·4 (68·3, 78·6) 44 Ref 2·2 (1·3, 3·1) 2·2 (1·3, 3·1) N/A 2·2 (1·3, 3·1)
29
Most deprived (Q5) 70·0 (64·7, 75·4) 101·7 (93·9, 109·5) 45 0·167 2·8 (1·4, 4·3) 2·8 (1·4, 4·3) N/A 2·8 (1·4, 4·3)
Community diagnosis 51·6 (49·5, 53·6) 60·8 (58·1, 63·5) 18 Ref 1·2 (0·3, 2·2) 4·2 (1·6, 6·8) 2004 -0·4 (-1·2, 0·5)
Hospital diagnosis 80·4 (75·4, 85·3) 109·1 (104·5, 113·6) 36 <0·0001 2·4 (1·4, 3·30) 2·4 (1·4, 3·30) N/A 2·4 (1·4, 3·30)
With the exception of age groups, all predictions are at the mean population age (78 years). Follow up was until death or study end. Relative diff., relative difference; py, person-years; CI, confidence interval. a relative percentage difference in admission rates (per 100 person-years) between the first and second diagnosis time periods, calculated by 100*([time-period 2 – time period 1] / time-period 1].b P value for the difference in trend lines between groups. Estimated by fitting an interaction term between calendar year and group in the negative binomial models also containing age. Estimated by fitting an interaction term between calendar year and group in the Poisson models also containing age. As interaction tests have low power, p-values should be interpreted along with the graphical trends (Figure 1)c Average annual percentage change in rates (per 100 person-years) for each increasing year of diagnosisd Change in slope estimated using Joinpoint regression.
30
651
Table 3 Predicted rates of death following HF diagnosis by population groups and calendar year
Deaths in first month N (%) Predicted rate per 100 py (95% CI)Relative diff. (%)a
P interactionb
Average annual percent change per year (95% CI)c
Slope changeAnnual percent change before and after break (95% CI)d
1998-2001 2012-2015 1998-2001 2012-2015 Before Break After
Rates during the first year following heart failure diagnosis in those who survived the first month
All 2,397 (14) 1,967 (11) 24·5 (23·4, 25·7) 23·0 (22·0, 24·1) -6 -0·5 (-0·9, -0·2) -0·5 (-0·9, -0·2) N/A -0·5 (-0·9, -0·2)
<70 years 328 (10) 186 (5) 13·6 (12·1, 15·1) 8·9 (7·9, 10·0) -35 -3·6 (-4·9, -2·3) -3·6 (-4·9, -2·3) N/A -3·6 (-4·9, -2·3)
70 to 79 years 684 (11) 301 (7) 21·8 (20·2, 23·4) 15·8 (14·4, 17·3) -28 0·113 -2·3 (-3·0, -1·6) -2·3 (-3·0, -1·6) N/A -2·3 (-3·0, -1·6)
80 to 89 years 1,004 (16) 901 (13) 32·6 (30·4, 34·8) 34·1 (31·9, 36·3) 5 <0·0001 0·3 (-0·1, 0·8) 0·3 (-0·1, 0·8) N/A 0·3 (-0·1, 0·8)
90 years and over 381 (21) 579 (22) 58·1 (51·5, 64·7) 69·6 (63·2, 76·0) 20 <0·0001 1·2 (0·0, 2·4) 1·2 (0·0, 2·4) N/A 1·2 (0·0, 2·4)
Men 1,103 (13) 926 (10) 29·2 (27·4, 31·0) 23·5 (22·1, 24·9) -20 -1·4 (-2·3, -0·5) -2·6 (-3·4, -1·7) 2009 0·8 (-1·7, 3·3)
Women 1,294 (14) 1,041 (12) 20·7 (19·5, 22·0) 22·0 (20·7, 23·4) 6 <0·0001 0·3 (-0·5, 1·1) 0·3 (-0·5, 1·1) N/A 0·3 (-0·5, 1·1)
Most affluent (Q1) 375 (13) 367 (10) 23·8 (21·3, 26·2) 21·1 (19·1, 23·1) -11 -0·8 (-1·2, -0·4) -0·8 (-1·2, -0·4) N/A -0·8 (-1·2, -0·4)
Most deprived (Q5) 476 (14) 310 (11) 27·6 (24·8, 30·4) 25·7 (22·9, 28·5) -7 0·46 -0·2 (-1·2, 0·8) -0·2 (-1·2, 0·8) N/A -0·2 (-1·2, 0·8)
Community diagnosis 1,449 (11) 606 (7) 20·8 (19·7, 21·8) 14·2 (13·2, 15·1) -32 -2·7 (-3·2, -2·2) -2·7 (-3·2, -2·2) N/A -2·7 (-3·2, -2·2)
Hospital diagnosis 948 (19) 1,361 (15) 38·8 (35·8, 41·8) 34·3 (32·3, 36·2) -12 <0·0001 -1·1 (-1·8, -0·4) -1·1 (-1·8, -0·4) N/A -1·1 (-1·8, -0·4)
Rates after the first year following heart failure diagnosis in survivors of the first year
Deaths in first year N (%) Predicted rate per 100 py (95% CI)Relative diff· (%)a
P interactionb
Average annual percent change per year (95% CI)c
Slope changeAnnual percent change before and after break (95% CI)d
1998-2001 2012-2015 1998-2001 2012-2015 1998-2001 2012-2015 1998-2001
All 5,475 (31) 5,143 (29) 17·6 (17·3, 18·0) 14·7 (14·3, 15·2) -16 -1·3 (-1·6, -1·1) -1·3 (-1·6, -1·1) N/A -1·3 (-1·6, -1·1)
<70 years 682 (20) 479 (13) 8·0 (7·7, 8·4) 5·4 (4·9, 5·9) -33 -2·9 (-3·6, -2·1) -2·9 (-3·6, -2·1) N/A -2·9 (-3·6, -2·1)
70 to 79 years 1,638 (27) 872 (19) 14·6 (14·1, 15·0) 11·3 (10·5, 12·0) -23 0·001 -1·9 (-2·2, -1·6) -1·9 (-2·2, -1·6) N/A -1·9 (-2·2, -1·6)
80 to 89 years 2,274 (36) 2,363 (35) 23·7 (23·0, 24·5) 20·8 (19·8, 21·7) -12 <0·0001 -0·9 (-1·3, -0·6) -0·9 (-1·3, -0·6) N/A -0·9 (-1·3, -0·6)
90 years and over 881 (49) 1,429 (54) 38·3 (35·8, 40·8) 41·7 (38·8, 44·7) 9 <0·0001 0·4 (-0·1, 1·0) 0·4 (-0·1, 1·0 N/A 0·4 (-0·1, 1·0
31
Men 2,630 (31) 2,501 (27) 20·2 (19·6, 20·7) 15·1 (14·4, 15·8) -25 -2·2 (-2·5, -1·9) -2·2 (-2·5, -1·9) N/A -2·2 (-2·5, -1·9)
Women 2,845 (31) 2,642 (31) 15·8 (15·4, 16·2) 14·2 (13·5, 14·8) -10 <0·0001 -0·8 (-1·1, -0·5) -0·8 (-1·1, -0·5) N/A -0·8 (-1·1, -0·5)
Most affluent 908 (31) 1,000 (28) 16·2 (15·5, 16·9) 13·1 (12·2, 14·0) -19 -1·4 (-2·1, -0·7) -1·4 (-2·1, -0·7) N/A -1·4 (-2·1, -0·7)
Most deprived 1,056 (32) 782 (29) 20·2 (19·4, 21·1) 16·9 (15·5, 18·2) -16 0·600 -1·3 (-1·8, -0·9) -1·3 (-1·8, -0·9) N/A -1·3 (-1·8, -0·9)
Community diagnosis 3,452 (27) 1,656 (19) 16·7 (16·3, 17·1) 12·0 (11·5, 12·5) -28 -2·4 (-2·7, -2·1) -2·4 (-2·7, -2·1) N/A -2·4 (-2·7, -2·1)
Hospital diagnosis 2,023 (31) 3,487 (38) 21·4 (20·6, 22·2) 18·7 (17·9, 19·5) -13 <0·0001 -1·0 (-1·3, -0·7) -1·0 (-1·3, -0·7) N/A -1·0 (-1·3, -0·7)
Crude death rates are reported for the first month and first year following HF diagnosis as N (%); number and percentage. Death rates are reported for (i) the first year in people who survived the first month following diagnosisand (ii) for subsequent years in people who survived the first year following HF diagnosis. With the exception of age groups, all predictions are at the mean population age (78 years). Relative diff., relative difference; py, person-years; CI, confidence interval, Q; quintile.a relative percentage difference in death rates (per 100 person-years) between the first and second diagnosis calendar time periods, calculated by 100*([time-period 2 – time period 1] / time-period 1].b P value for the difference in trend lines between groups. Estimated by fitting an interaction term between calendar year and group in the Poisson models also containing age. As interaction tests have low power, p-values should be interpreted along with the graphical trends (Figure 2)c Average annual percentage change in rates (per 100 person-years) for each increasing year of diagnosisd Change in slope estimated using Joinpoint regression.
32
652
Table 4: Associations between population groups and outcomes
Hospital admissions Incidence rate ratio with 95% confidence intervals
Follow-up All CVD Non-CVDGroup Total
admissions Total py Median[IQR] Unadjusted Adjusteda Unadjusted Adjusteda Unadjusted Adjusteda
All 228,113 330,137 2·4 [0·5, 5·7]
<70 years 57,164 106,267 4·8 [ 1·6·, 9·2] 1·0 1·0 1·0 1·0 1·0 1·0
70 to 79 years 77,526 115,053 3·3 [0·9, 6·9] 1·31 (1·27, 1·34) 1·21 (1·18, 1·24) 1·29 (1·24, 1·34) 1·18 (1·13, 1·23) 1·31 (1·27, 1·35) 1·23 (1·20, 1·27)
80 to 89 years 76,565 91,903 1·8 [0·3, 4·2] 1·64 (1·60, 1·68) 1·47 (1·43, 1·51) 1·65 (1·59, 1·71) 1·45 (1·39, 1·52) 1·64 (1·59, 1·68) 1·49 (1·45, 1·54)
90 years and above 16,858 16,914 0·7 [0·1, 2·3] 1·94 (1·87, 2·01) 1·72 (1·65, 1·79) 1·89 (1·79, 1·99) 1·67 (1·57, 1·77) 1·95 (1·88, 2·03) 1·74 (1·67, 1·82)
Male (ref) 116,829 174,160 2·5 [0·5, 5·9] 1·0 1·0 1·0 1·0 1·0 1·0
Female 111,284 155,977 2·2 [0·4, 5·4] 1·05 (1·03,1·07) 0·91 (0·90,0·92) 0·97 (0·94, 1·00) 0·85 (0·83, 0·88) 1·09 (1·07,1·11) 0·90 (0·88,0·92)
Socioeconomic statusQ1 Most affluent (ref) 37,567 62,395 2·4 [0·5, 5·8] 1·0 1·0 1·0 1·0 1·0 1·0
Q2 50,412 76,813 2·4 [0·5, 5·7] 1·08 (1·05, 1·11) 1·05 (1·02, 1·08) 1·10 (1·05, 1·15) 1·06 (1·02, 1·11) 1·08 (1·04, 1·11) 1·05 (1·02, 1·08)
Q3 47,541 70,313 2·3 [0·4, 5·7] 1·13 (1·10, 1·17) 1·10 (1·07, 1·13) 1·14 (1·09, 1·19) 1·10 (1·05, 1·15) 1·13 (1·09, 1·17) 1·09 (1·06, 1·12)
Q4 48,043 65,182 2·4 [0·4, 5·6] 1·20 (1·16, 1·23) 1·14 (1·11, 1·18) 1·16 (1·11, 1·22) 1·12 (1·08, 1·17) 1·22 (1·18, 1·26) 1·16 (1·12, 1·19)
Q5 Most deprived 44,228 54,986 2·3 [0·4, 5·6] 1·34 (1·32,1·35) 1·20 (1·17,1·24) 1·23 (1·17, 1·29) 1·18 (1·13,1·19) 1·33 (1·28,1·37) 1·22 (1·21,1·25)
Community (ref) 135,050 234,304 3·3 [0·9, 6·9] 1·0 1·0 1·0 1·0 1·0 1·0
Hospital 93,063 95,833 1·3 [0·2, 3·8] 1·76 (1·73, 1·80) 1·52 (1·49, 1·55) 2·04 (1·98, 2·10) 1·77 (1·72, 1·82) 1·64 (1·63, 1·66) 1·40 (1·37, 1·43)
Deaths Hazard ratios with 95% confidence intervals
All CVD Non-CVDTotal deaths
N (%)Survival time
Mean (95% CI)Age at death
Median [IQR] Unadjusted Adjustedb Unadjusted Adjustedb Unadjusted Adjustedb
All 65,063 (74) 3·2 [3·1, 3·2] 84 [78, 90]
<70 years 8,859 (49) 9·0 [8·8, 9·3] 67 [62, 71] 1·0 1·0 1·0 1·0 1·0 1·0
70 to 79 years 18,517 (72) 4·5 [4·5, 4·6] 79 [76, 82] 1·88 (1·84, 1·93) 1·68 (1·64, 1·73) 1·77 (1·70, 1·83) 1·60 (1·54, 1·66) 2·00 (1·93, 2·08) 1·73 (1·66, 1·81)
80 to 89 years 27,568 (83) 2·2 [2·1, 2·2] 87 [84, 89] 3·27 (3·19, 3·36) 2·66 (2·58, 2·74) 3·15 (3·04, 3·26) 2·59 (2·49, 2·70) 3·33 (3·20, 3·46) 2·61 (2·49, 2·73)
90 years and above 10,119 (90·2) 0·8 [0·8, 0·9] 94 [ 92, 96] 5·59 (5·42, 5·76) 4·08 (3·93, 4·22) 5·30 (5·08, 5·52) 3·95 (3·76, 4·15) 5·84 (5·57, 6·12) 4·05 (3·82, 4·29)
Male (ref) 31,819 (71) 3·5 [3·4, 3·5] 82 [75, 88] 1·0 1·0 1·0 1·0 1·0 1·0
Female 33,244 (76) 2·9 [2·8, 2·9] 86 [80, 91] 1·15 (1·13, 1·17) 0·85 (0·83, 0·86) 1·11 (1·09, 1·13) 0·85 (0·83, 0·88) 1·21 (1·18, 1·24) 0·84 (0·82,0·87)
Socioeconomic statusQ1 Most affluent (ref) 11,645 (71) 3·4 [3·3, 3·5] 86 [80, 90] 1·0 1·0 1·0 1·0 1·0 1·0
33
Q2 15,093 (74) 3·2 [3·3, 3·5] 85 [79, 90] 1·05 (1·03, 1·08) 1·05 (1·03, 1·08) 1·07 (1·04, 1·11) 1·09 (1·05, 1·12) 1·02 (0·98, 1·06) 1·01 (0·97, 1·05)
Q3 14,065 (74) 3·1 [3·0, 3·2] 85 [89, 90] 1·07 (1·04, 1·10) 1·07 (1·05, 1·10) 1·11 (1·07, 1·15) 1·12 (1·09, 1·16) 1·03 (1·00, 1·08) 1·02 (0·98, 1·06)
Q4 12,971 (74) 3·1 [3·0, 3·2] 84 [77, 89] 1·06 (1·04, 1·09) 1·11 (1·09, 1·14) 1·06 (1·02, 1·10) 1·12 (1·09, 1·17) 1·06 () 1·02, 1·11) 1·10 (1·06, 1·14)
Q5 Most deprived 11,149 (75) 3·1 [2·9, 3·2] 82 [75, 88] 1·08 (1·05, 1·11) 1·17 (1·14, 1·21) 1·06 (1·02, 1·10) 1·18 (1·14, 1·23) 1·12 (1·07, 1·16) 1·17 (1·13, 1·22)
Community (ref) 37,734 (73) 4·2 [4·2, 4·3] 84 [78, 90] 1·0 1·0 1·0 1·0 1·0 1·0
Hospital 27,329 (75) 1·9 [1·8, 1·9] 85 [78, 90] 1·55 (1·53, 1·58) 1·46 (1·43, 1·48) 1·72 (1·69, 1·76) 1·55 (1·51, 1·59) 1·28 (1·25, 1·31) 1·37 (1·34, 1·40)
IRR; Incidence rate ratio, CI; Confidence interval, py; person-years, IQR; interquartile range, Q; quintilea adjusted for age gender socioeconomic status, ethnicity, place of diagnosis, calendar year, beta-blocker, angiotensin converting enzyme inhibitor, angiotensin receptor blocker; aldosterone antagonist, aspirin, loop diuretic, number of comorbidities, ischaemic heart disease, myocardial infarction, atrial fibrillation, hypertension, diabetes, stroke, anaemia, obesity, chronic kidney disease, chronic obstructive pulmonary disease, asthma, depression, osteoarthritis, cancer and dementia, smoking, alcohol, body mass index, systolic blood pressure, cholesterol, haemoglobin and estimated glomerular filtration rate.
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Figure 1
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Figure 2
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Figure legends
Figure 1 Trends in predicted 1-year rates of cause-specific hospitalisations at mean age
of 78 years
Predicted admission rates at mean population age (78 years) per 100 person-years by cause
between 1998 and 2015. Follow up was until death or study end. Spikes indicate 95% CI. P-
values are for the test of difference in trends. As interaction tests have low power, p-values
should be interpreted along with the graphical trends.
Figure 2. First year mortality rates by population group and calendar year of diagnosis
Predicted mortality rates at mean population age (78 years) per 100 person-years between
1998 and 2015. Spikes indicate 95% CI. Rates were calculated in survivors of the first month
following HF diagnosis. P-values are for the test of difference in trends. As interaction tests
have low power, p-values should be interpreted along with the graphical trends.
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