04 diagnostic micro 5-30-06
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I. OVERVIEW
Identification of the organism causing an infectious process is usually
essential for effective antimicrobial and supportive therapy. Initial treat-
ment may be empiric, based on the microbiologic epidemiology of the
infection and the patient’s symptoms. However, definitive microbiologic
diagnosis of an infectious disease usually involves one or more of the
fo l l owing five basic labora t o ry techniques, which guide the phy s i c i a n
along a narrowing path of possible causative organisms: 1) direct micro-
scopic visualization of the organism; 2) cultivation and identification of
the organism; 3) detection of microbial antigens; 4) detection of micro-
bial DNA or RNA; and 5) detection of an inflammatory or host immune
response to the microorganism (Figure 4.1).
II. SENSITIVITY AND SPECIFICITY OF TEST RESULTS
I n t e rpretation of labora t o ry tests is influenced by the reliability of the
r e s u l t s. Ideally, a diagnostic test is positive in the presence of a pathogen
( t ru e - p o s i t i ve) and negative in the absence of a pathogen (tru e - n e g a-
t i ve). Howeve r, in pra c t i c e, no labora t o ry test is perfect. An assay may
g i ve negative results in the presence of a pathogen (fa l s e - n e g a t i ve) or
p o s i t i ve results in the absence of a pathogen (fa l s e - p o s i t i ve). Thus, it is
useful to define the reliability of a diagnostic procedure in terms of its
sensitivity and specificity. The sensitivity of a test is the probability that it
will be positive in the presence of a pathogen:
Sensitivity = True-positives
x 100 percentTrue-positives + False-negatives
As the number of fa l s e - n e g a t i ves approaches ze r o, the sensitivity
approaches 100 percent (that is, all infected patients are detected).
Specificity is the probability that a test will be negative if the pathogen is
not present:
Specificity = True-negatives
x 100 percentTrue-negatives + False-positives
As the number of fa l s e - p o s i t i ves approaches ze r o, the specificity
approaches 100 percent (that is, all positive patients are actually
DiagnosticMicrobiology 4
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A. Gram stain
Because unstained bacteria are difficult to detect with the light
m i c r o s c o p e, most patient material is stained prior to microscopic
evaluation. The most common and useful staining procedure—the
Gram stain—separates bacteria into two classifications according to
the composition of their cell walls. If a clinical specimen on a micro-
scope slide is treated with a solution of crystal violet and then
i o d i n e, the bacterial cells will stain purp l e. If the stained cells are
then treated with a solvent, such as alcohol or acetone, gra m -
positive organisms retain the stain, whereas gram-negative species
lose the stain, becoming colorless (Figure 4.3). Addition of the
counterstain safranin stains the clear, gra m - n e g a t i ve bacteria pink
or red. Most, but not all, bacteria are stainable and fall into one of
these two groups. [Note: Microorganisms that lack cell walls, such
as mycoplasma, cannot be identified using the Gram stain.]
1. Applications of the Gram stain: The Gram stain is important ther-
apeutically because gra m - p o s i t i ve and gra m - n e g a t i ve bacteri a
have differing susceptibilities to various antibiotics, and the Gram
stain may, therefore, be used to guide initial therapy until definitive
identification of the microorganism can be obtained. In addition,
the morphology of the stained bacteria can sometimes be diag-
nostic; for example, gram-negative intracellular diplococci in ure-
t h ral pus provides a presumptive diagnosis of gonorrhea. Gra m
stains of specimens submitted for culture are often invaluable aids
in the interpretation of culture results. For ex a m p l e, a specimen
may show organisms under the microscope, but appear sterile in
culture media. This discrepancy may suggest: 1) fastidious organ-
isms (bacteria with complex nu t rient requirements) that are
unable to grow on the culture media employed; or 2) fragile organ-
isms, such as gonococcus or anaerobic organisms, that may not
s u rv i ve tra n s p o rt. In these cases, direct visualization with the
Gram stain may provide the only clue to the nature, variety, and
relative number of infecting organisms.
2. Limitations of the Gram stain: The number of microorganisms
required is relatively high––visualization with the Gram stain
requires greater than 104 organisms/mL. Liquid samples with low
IV. Direct Visualization of the Organism 2120 4. Diagnostic Microbiology
infected). Figure 4.2 shows the results obtained with tests of high and
low sensitivity/specificity.
III. PATIENT HISTORY AND PHYSICAL EXAMINATION
A clinical history is the most important part of the evaluation of patients.
For example, a history of cough points to the possibility of respiratory
tract infection; dysuria suggests urinary tract infection. A history of travel
to developing countries may implicate exotic organisms. For example, a
patient who recently swam in the Nile has an increased risk of schisto-
s o m i a s i s. Patient occupations may suggest exposure to cert a i n
pathogens, such as brucellosis in a butcher or anthrax in farmers. Even
the age of the patient can sometimes guide the clinician in predicting
the identity of pathogens, for ex a m p l e, a gra m - p o s i t i ve coccus in the
spinal fluid of a newborn infant is unlikely to be Streptococcus pneumo-
n i a e (pneumococcus), but most likely to be S. agalactiae (Group B).
This organism is sensitive to penicillin G. By contrast, a gram-positive
coccus in the spinal fluid of a forty-year-old is most likely to be Strep-
tococcus pneumoniae. This organism is frequently resistant to penicillin
G, and often requires treatment with a third generation cephalospori n
(such as cefotaxime or ceftriaxone) or vancomycin. The etiology implied
by the patient’s age may thus guide initial therapy. A physical examina-
tion often provides confirmatory clues to the presence and extent (local-
i zed or disseminated) of disease. For ex a m p l e, erythema migrans (a
large skin lesion with a bright red outer border and partially clear central
area, see p. 1 6 5) indicates early localized Lyme disease. Clues to the
presence of bacteremia (a disseminated infection) may include chills,
fever (or sometimes hypothermia), or cardiovascular instability heralding
septic shock. Physical signs of pulmonary consolidation suggest pneu-
monia. If one adds stupor and stiff neck to this constellation of findings,
the organism causing the pneumonia may have spread to the
meninges, warranting a further search for it in the cerebrospinal fluid.
All labora t o ry studies must be directed by the
p a t i e n t ’s history and physical examination and
then evaluated, taking into consideration the sen-
sitivity and specificity of the test.
IV. DIRECT VISUALIZATION OF THE ORGANISM
In many infectious diseases, pathogenic organisms can often be directly
v i s u a l i zed by microscopic examination of patient specimens, such as
sputum, urine, or cerebrospinal fluid. The organism’s microscopic mor-
phology and staining characteristics can provide the first screening step
in arriving at a specific identification. The organisms to be ex a m i n e d
need be neither alive nor able to multiply. Microscopy gives rapid and
i n ex p e n s i ve results, and may allow the clinician to initiate treatment
without waiting for the results of a culture, as noted in the spinal fluid
example in the previous paragraph.
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numbers of microorganisms (for example, in cerebrospinal fluid),
require centrifugation to concentrate the pathogens. The pellet is
then examined after staining.
B. Acid-fast stain
Stains such as Ziehl-Neelsen (the classic acid-fast stain) are used
to identify organisms that have waxy material (mycolic acids) in
their cell wa l l s. Most bacteria that have been stained with carbol-
fuchsin can be decolori zed by washing with acidic alcohol.
H oweve r, certain acid-fast bacteria, retain the carbolfuchsin stain
after being washed with an acidic solution. The most clinically
i m p o rtant acid-fast bacterium is M y c o b a c t e rium tuberculosis, which
appears pink, often beaded, and slightly curved (Figure 4.4). Acid-
fast staining is reserved for clinical samples from patients sus-
pected of having my c o b a c t e rial infe c t i o n .
C. India ink preparation
This is one of the simplest microscopic methods. It is useful in
detecting C ryptococcus neofo rm a n s in cerebrospinal fluid (Figure
4.5). One drop of centrifuged cerebrospinal fluid is mixed with one
drop of India ink on a microscope slide beneath a glass cover slip.
C ryptococci are identified by their large, transparent capsules that
displace the India ink particles.
D. Potassium hydroxide (KOH) preparation
Treatment with KOH dissolves host cells and bacteria, sparing fungi
(Figure 4.6). One drop of sputum or skin scraping is treated with ten
percent KOH, and the specimen is examined for fungal forms.
V. GROWING BACTERIA IN CULTURE
Culturing is routine for most bacterial and fungal infections, but is rarely
used to identify helminths or protozoa. Culturing of many pathogens is
straightforward, for example, streaking a throat swab onto a blood agar
plate in search of group A β-hemolytic streptococcus. However, certain
pathogens are very slow growing (for example, Mycobacterium tubercu-
losis), or are cultured only with difficulty (for example, Bartonella hense-
l a e). Microorganisms isolated in culture are identified using such
characteristics as colony size, shape, color, Gram stain, hemolytic reac-
tions on solid media, odor, and metabolic properties. In addition, pure
cultures provide samples for antimicrobial susceptibility testing (see
p. 3 0). The success of culturing depends on appropriate collection and
t ra n s p o rt techniques, and on selection of appropriate culture media,
because some organisms may require special nu t ri e n t s. A l s o, some
media are used to suppress the growth of certain organisms in the pro-
cess of identifying others (see p. 2 3)
A. Collection of specimens
Many organisms are fragile and must be transported to the labora-
t o ry with minimal delay; for ex a m p l e, gonococci and pneumococci
are ve ry sensitive to heating or drying. Samples must be cultured
22 4. Diagnostic Microbiology V. Growing Bacteria in Culture 23
promptly or, if this is not possible, transport media must be used to
extend the viability of the organism to be cultured. When anaerobic
organisms are suspected, the patient’s specimen must be protected
from the toxic effect of oxygen (Figure 4.7).
B. Growth requirements
All clinically important bacteria are heterotrophs (that is, they require
organic carbon for growth). Heterotrophs may have complex or sim-
ple requirements for organic molecules. [Note: Organisms that can
reduce carbon dioxide and, thus, do not require organic compounds
for cell growth, are called autotrophs.] Most bacteria require varying
numbers of growth factors, which are organic compounds required
by the cell to grow, but which the organism cannot itself synthesize
(for example, vitamins). Organisms that require either a large num-
ber of growth factors or must be supplied with very specific ones are
referred to as fastidious.
C. Oxygen requirement:
B a c t e ria can be categori zed according to their gr owth responses in
the presence and absence of oxygen. Aerobic bacteria (aerobes)
such as M. tuberculosis, gr ow in the presence of oxygen, and can
use oxygen as the terminal electron acceptor in energy production
(see p. 185). Obligate aerobes have an absolute requirement for ox y-
gen. Fa c u l t a t i ve organisms, such as E s c h e richia coli, gr ow in the
presence or absence of oxygen. The “true” fa c u l t a t i ves use ox y g e n
p r e ferentially as the terminal electron acceptor when it is present,
whereas microaerophilic organisms, such as C a m pylobacter jejuni,
require or tolerate oxygen, but at an oxygen partial pressure lowe r
than that of the atmosphere. Anaerobic bacteria such as C l o s t ri d i u m
b o t u l i nu m can gr ow in the absence of oxygen, producing energy by
fe rmentation (see p. 153), whereas obligate anaerobes gr ow only in
the absence of oxygen and may, in fact, be killed by small amounts of
ox y g e n .
D. Media
Two general strategies are used to isolate pathogenic bacteri a ,
depending on the nature of the clinical sample. The first method
uses enriched media to promote the nonselective growth of any bac-
teria that may be present. The second approach employs selective
media that only allow growth of specific bacterial species from speci-
mens that normally contain large numbers of bacteria (for example,
stool, genital tract secretions, or sputum).
Isolation of a bacterium is usually performed on
solid medium. Liquid medium is used to gr ow
larger quantities of a culture of bacteria that has
already been isolated as a pure culture).
1. Enriched media: Media fo rtified with blood, yeast ex t ra c t s, or bra i n
or heart infusions are useful in gr owing fastidious organisms. Fo r
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VI. IDENTIFICATION OF BACTERIA
The most widely used identification scheme invo l ves determining the
m o rphologic and metabolic properties of the unknown bacterium, and
c o m p a ring these with properties of known microorganisms. Altern a t e
identification schemes using nucleic acid–based methods are dis-
cussed on p. 2 9. Immunologic methods used in diagnosis are described
on p. 2 6. It is essential to start identification tests with pure bacterial iso-
lates grown from a single colony.
A. Single-enzyme tests
D i f ferent bacteria produce va rying spectra of enzymes. For ex a m-
p l e, some enzymes are necessary for the bacteri u m ’s individual
metabolism and some facilitate the bacteri u m ’s ability to compete
with other bacteria or establish an infection. Tests that measure sin-
gle bacterial enzymes are simple, rapid, and generally easy to inter-
pret. They can be performed on organisms already grown in culture,
and often provide presumptive identification.
1. Catalase test: The enzyme catalase catalyzes the degradation of
hydrogen peroxide to water and molecular oxygen (H2O2 → H2O
+ O2). Catalase-positive organisms rapidly produce bu bbl e s
when exposed to a solution containing hydrogen peroxide (Figure
4.9). The catalase test is key in differentiating between many
gra m - p o s i t i ve organisms; for ex a m p l e, staphylococci are cata-
l a s e - p o s i t i ve, whereas streptococci and enterococci are catalase-
n e g a t i ve.
2. Oxidase test: The enzyme cytochrome oxidase is part of electron
t ra n s p o rt and nitrate metabolism in some bacteria. The enzyme
can accept electrons from ar tificial substra t e s, such as a
phenylenediamine derivative, producing a dark, oxidized product
(see Figure 4.9). This test assists in differentiating betwe e n
groups of gram-negative bacteria. Pseudomonas aeruginosa, for
example, is oxidase-positive.
3. Urease: The enzyme urease hydrolyzes urea to ammonia and car-
bon dioxide (NH2CONH2 + H2O → 2NH3 + CO2). The ammonia
produced can be detected with pH indicators that change color in
response to the increased alkalinity (see Figure 4.9). The test
helps to identi fy cer tain species of Enterobacter i a c e a e,
Corynebacterium urealyticum and Helicobacter pylori.
4. Coagulase test: Coagulase is an enzyme that causes a clot to
form when bacteria are incubated with plasma. The test is used to
d i f ferentiate S t a p hylococcus aureus ( c o a g u l a s e - p o s i t i ve) from
coagulase-negative staphylococci.
B. Tests based on the presence of metabolic pathways
These tests measure the presence of a metabolic pathway in a bac-
terial isolate, rather than a single enzyme. Commonly used assays
include those for oxidation and fe rmentation of different carbohy-
drates, the ability to degrade amino acids, and use of specific sub-
24 4. Diagnostic Microbiology VI. Identification of Bacteria 25
ex a m p l e, sheep blood agar contains protein sources, sodium chlo-
ri d e, and five percent sheep blood, and supports the gr owth of
most gra m - p o s i t i ve and gra m - n e g a t i ve bacteria isolated from
human sources (see p. 89). Howeve r, Haemophilus influenzae a n d
N e i s s e ria gonorrhoeae, among others, are highly fastidious organ-
i s m s. They require chocolate agar, which contains red blood cells
that have been lysed (see p. 131). This releases intracellular nu t ri-
e n t s, such as hemoglobin, hemin (“X” factor), and NAD+ (“V” fa c-
tor), required by these o r g a n i s m s. Enriched media are useful fo r
c u l t u ring normally sterile body fluids, such as blood or cere-
brospinal fluid, in which the finding of any organisms provides rea-
s o n a ble evidence for infection due to that organism.
Failure to culture an organism may indicate that
the culture medium is inadequate, or the incuba-
tion conditions do not support bacterial growth.
2. Selective media: The most commonly used selective medium is
MacConkey agar (see p. 1 1 5), which supports the growth of most
gra m - n e g a t i ve rods, especially the Enterobacteri a c e a e, bu t
inhibits gr owth of gra m - p o s i t i ve organisms and some fa s t i d i o u s
gra m - n e g a t i ve bacteria, such as H a e m o p h i l u s and N e i s s e ri a
s p e c i e s. Growth on blood agar and chocolate agar, but not
MacConkey agar suggests a gram-positive isolate or a fastidious
gra m - n e g a t i ve species. In contrast, most gra m - n e g a t i ve rods
often fo rm distinctive colonies on MacConkey agar. This agar is
also used to detect organisms able to metabolize lactose (Figure
4.8). Clinical samples are routinely plated on blood agar, choco-
late agar, and MacConkey agar. Hektoen enteric agar is also a
s e l e c t i ve medium that differentiates lactose/sucrose fe rm e n t e r s
and nonfermenters, as well as H2S producers and nonproducers.
It is often used to culture S a l m o n e l l a and S h i g e l l a s p e c i e s.
T h aye r - M a rtin agar is another selective medium composed of
chocolate agar supplemented with seve ral antibiotics that sup-
press the gr owth of nonpathogenic N e i s s e ri a and other norm a l
and abnormal flora. This medium is normally used to isolate
gonococci.
When submitting samples for culture, the physi-
cian must alert the laboratory to likely pathogens
w h e n ever possibl e, especially when unu s u a l
organisms are suspected. This allows inclusion
of selective media that might not be used rou-
tinely. It also alerts the laboratory to hold speci-
mens longer, if a slow - gr owing organism, such
as Nocardia, is suspected.
04 Diagnostic Micro 5-30-06 6/8/06 9:20 AM Page 24
s t ra t e s. A widely used manual system for rapid identification of
members of the family Enterobacteriaceae and other gram-negative
bacteria makes use of twenty microtubes containing substrates for
various biochemical pathways. The test substrates in the microtubes
are inoculated with the bacterial isolate to be identified, and, after
five hours’ incubation, the metabolic profile of the organism is con-
structed from color changes in the microtubes. These color changes
indicate the presence or absence of the bacteria’s ability to metabo-
l i ze a particular substra t e. The results are compared with a data
bank containing test results from known bacteria (Figure 4.10). The
probability of a match between the test organism and know n
pathogens is then calculated.
C. Automated systems
Microbiology laboratories are increasingly using automated methods
to identify bacterial pathogens. For ex a m p l e, in the Vitek System,
small plastic reagent cards containing microliter quantities of various
biochemical test media in thirty wells provide a biochemical profile
that allows for organism identification (Figure 4.11). An inoculum
derived from cultured samples is automatically transferred into the
card, and a photometer intermittently measures color changes in the
card that result from the metabolic activity of the organism. The data
are analyzed, stored, and printed in a computerized data base.
VII. IMMUNOLOGIC DETECTION OF MICRO O R G A NISMS
In the diagnosis of infectious diseases, immunologic methods take
a d vantage of the specificity of antigen-antibody binding. For ex a m p l e,
known antigens and antibodies are used as diagnostic tools in identify-
ing microorganisms. In addition, serologic detection of a patient’s
immune response to infection, or antigenic or nucleic acid evidence of a
pathogen in a patient’s body fluids, is frequently useful. I m mu n o l o g i c
methods are useful when the infecting microorganism is difficult or
i m p o s s i ble to isolate, or when a previous infection needs to be docu-
mented. Most methods for determining whether antibodies or antigens
are present in patients’ sera or other body fluids require some type of
immunoassay procedure, such as those described in this section.
A. Detection of microbial antigen with known antiserum
These methods of identification are often rapid, and show favorable
sensitivity and specificity (see Figure 4.2, p. 2 0). Howeve r, unlike
microbial culturing techniques, these immunologic methods do not
permit further characterization of the microorganism, such as deter-
mining its antibiotic sensitivity, or characteristic metabolic patterns.
1. Capsular swelling reaction: Some bacteria having capsules can
be identified directly in clinical specimens by a swelling reaction
that occurs when the organisms are treated with serum contain-
ing specific antibodies (see Figure 9.10, p. 8 6). This method,
sometimes called the Quellung reaction, can be used for all
serotypes of S. pneumoniae, H. influenzae type b, and N e i s s e ri a
m e n i n g i t i d i s groups A and C.
2. Slide agglutination test: Some microorganisms, such as
Salmonella and Shigella species, can be identified by agglutina-
tion (clumping) of a suspension of bacterial cells on a microscopic
s l i d e. Agglutination occurs when a specific antibody directed
against the microbial antigen is added to the suspension, causing
cross-linking of the bacteria.
B. Identification of serum antibodies
Detection in a patient’s serum of antibodies that are directed against
microbial antigens provides evidence for a current or past infection
with a specific pathogen. A discussion of the general interpretation
of antibody responses includes the following rules: 1) antibody may
not be detectable early in an infection; 2) the presence of antibodies
in a patient’s serum cannot differentiate between a present and a
prior infection; and 3) a rise in antibody titer over a seven-to-ten day
p e riod does distinguish between a present or prior infe c t i o n .
Techniques such as complement fixation and agglutination can be
used to quantitate antimicrobial antibodies.
1. Complement fixation: One older but still useful method for detect-
ing serum antibody directed against a specific pathogen employs
the ability of antibody to bind complement (Figure 4.12). A
patient’s serum is first incubated with antigen specific for the sus-
pected infectious agent, followed by the addition of complement. If
the patient’s serum does contain IgG or IgM antibodies that target
the specific antigen (indicating past or current infection), then the
added complement will be sequestered in an antigen-antibody-
complement complex (“complement fixation”). Next, sensitize d
(antibody-coated) indicator sheep red blood cells are added to the
solution. If complement has been fixed (because the patient’s
serum contained antibodies against the added antigen), then little
complement will be ava i l a ble to bind to the antibody–red bl o o d
cell complexes, and the cells will not lyse. If complement has not
been depleted by initial antigen-antibody complexes (because the
p a t i e n t ’s serum does not contain antibodies to the specific anti-
gen), the complement will bind to the antibody–red blood cell
c o m p l exe s, causing the cells to lyse. As hemolyzed red bl o o d
cells release hemoglobin, the reaction can be monitored with a
spectrophotometer.
26 4. Diagnostic Microbiology VII. Immunologic Detection of Microorganism 27
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2. Direct agg l u t i n a t i o n : “ Fe b rile agglutinins” is a test panel some-
times ordered to evaluate patients with fever of unknown ori g i n ,
or when a suspected organism is difficult or dangerous to culture
in the labora t o ry. This test measures the ability of a patient's
s e rum antibody to directly agglutinate specific killed (yet intact)
m i c r o o r g a n i s m s. This test is used to evaluate patients suspected
of being infected by B rucella abort u s or Francisella tularensis,
among others.
3. Direct hemagg l u t i n a t i o n : Antibodies directed against red bl o o d
cells can arise during the course of various infections. For exam-
ple, such antibodies are typically found during infectious mononu-
cleosis caused by Epstein-Barr virus (see p. 268). When
uncoated (native) animal or human red blood cells are used in
agglutination reactions with serum from a patient infected with
such an organism, antibodies to red blood cell antigens can be
detected (the patient’s antibodies cause the red blood cells to
clump). This test is, therefore, a direct hemagglutination reaction.
In the case of some diseases, including pneumonia caused by
Mycoplasma pneumoniae, IgM autoantibodies may develop that
agglutinate human red blood cells at 4oC but not at 37oC. This is
termed the “cold agglutinins” test.
C. Other tests used to identify serum antigens or antibodies
1. Latex agglutination test: Latex and other particles can be readily
coated with either antibody (for antigen detection) or antigen (for
antibody detection). Addition of antigen to antibody-coated latex
beads causes agglutination that can be visually observed (Figure
4.13). For example, such methods are used to rapidly test cere-
b ral spinal fluid for antigens associated with common fo rms of
b a c t e rial or fungal meningitis. When antigen is coated onto the
latex bead, antibody from a patient’s serum can be detected.
Latex agglutination tests are widely used for the
identification of β-hemolytic streptococci group A.
2. Enzyme-linked immunosorbent assay (ELISA): In this diagnostic
technique, antibody specific for an antigen of interest is bound to
the walls of a plastic microtiter well (Figure 4.14). Patient serum is
then incubated in the we l l s, and any antigen in the serum is
bound by the antibody on the well wa l l s. The wells are then
washed, and a second antibody is added––this one also specific
for the antigen, but recognizing epitopes different from those
bound by the first antibody. After incubation, the wells are again
washed, removing any unattached antibody. Attached to the sec-
ond antibody is an enzyme, which, when presented with its sub-
s t ra t e, produces a colored product, the intensity of the color
produced being proportional to the amount of bound antigen.
ELISAs can also be used to detect or quantitate antibody in a
patient’s serum. In this instance, the wells are coated with antigen
specific for the antibody in question. The patient’s serum is
a l l owed to react with the bound antigen, the wells are wa s h e d ,
and a secondary antibody (that recognizes the initial antibody)
conjugated to a color product-producing enzyme is added to the
well. After a final washing, substrate for the bound enzyme is
added to the well, and the intensity of the colored product can be
measured.
3. Fluorescent-antibody tests: Organisms in clinical samples can be
detected directly by specific antibodies coupled to a fluorescent
compound, such as fluorescein. In the direct immu n o f l u o r e s c e n c e
antibody technique, a sample of concentrated body fluid (for ex a m-
p l e, CSF or serum), tissue scraping (for ex a m p l e, skin), or cells in
tissue culture is incubated with a fluorescein-labeled antibody
directed against a specific pathogen. The labeled antibody bound
to the microorganism absorbs ultraviolet light, and emits visible flu-
orescence that can be detected by the human eye, using a fluores-
cence microscope. A va riation of the technique, the indirect
i m munofluorescence antibody technique, invo l ves the use of two
a n t i b o d i e s. The first, unlabeled antibody (the target antibody) binds
a specific microbial antigen in a sample such as those descri b e d
a b ove. This clinical sample is subsequently stained with a fluores-
cent antibody that recognizes the target antibody. Because a nu m-
ber of labeled antibodies can bind to each target antibody, the
fluorescence from the stained microorganism is intensified.
VIII. DETECTION OF MICROBIAL DNA OR RNA
A highly specific method of pathogen detection involves identification of
its DNA or RNA in a patient sample. The basic strategy is to detect a
r e l a t i vely short sequence of nucleotide bases of DNA or RNA (target
sequence) that is unique to the pathogen. This is done by hybridization
with a complementary sequence of bases, referred to as the probe.
[Note: In bacteria, DNA sequences coding for 16S ribosomal RNA
sequences (rRNA) are commonly used targets, because each microor-
ganism contains multiple copies of its specific rRNA gene, thus increas-
ing the sensitivity of the assay.] The methods for detecting microbial
DNA or RNA fall into two categories: direct hybridization, and amplifica-
tion methods using the polymerase chain reaction1 or one its variations.
A. Direct hybridization methods
These methods use a probe—a single-stranded piece of DNA, usu-
ally labeled with an enzyme, fluorescent molecule, ra d i o a c t i ve
label, or some other detectable molecule. The nucleotide sequence
of the probe is complementary to the DNA of interest (the target
DNA). To obtain the target DNA, an appropriate sample from the
patient is cultured to increase the number of the presumptive dis-
ease-causing microorganisms, and then treated, so that the
28 4. Diagnostic Microbiology VIII. Detection of Microbial DNA or RNA 29
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microorganisms lyse, releasing DNA. Single-stranded DNA, pro-
duced by alkaline denaturation of the double-stranded DNA, is first
bound to a solid support such as a nitrocellulose membra n e. The
immobilized DNA strands are then available for hybridization to the
microorganism-specific, labeled probe. Unbound probe is removed
by washing the filter, and the extent of hy b ridization is then mea-
sured by the retention of the labeled probe on the filter.
B. Amplification methods
Methods employing nucleic acid amplification techniques, such as
the polymerase chain reaction (PCR2), have a major advantage over
direct detection with nucleic acid probes because amplification
methods allow specific DNA or RNA target sequences of the
pathogen to be amplified millions of times without having to culture
the microorganism itself for extended periods.
Nucleic acid amplification methods are sensitive,
specific for the target organism, and are un-
affected by the prior administration of antibiotics.
1. Applications: Nucleic acid amplification techniques are generally
quick, easy, and accurate. A major use of these techniques is for
the detection of organisms that cannot be gr own in vitro, or fo r
which current culture techniques are insensitive. Further, they are
useful in the detection of organisms that require complex media or
cell cultures and/or prolonged incubation times.
2. Detection: Amplified sequences are detected by va rious meth-
ods; for ex a m p l e, agarose gel electrophoresis or blotting the
product onto a membrane such as a nitrocellulose filter, fo l l owe d
by probe hy b ridization (as described above). Newer detection
methods capture the amplified target sequences in a well, using
a complementary strand of DNA that has been fixed to the sur-
face of the well.
3. Limitations: PCR amplification is limited by the occurrence of spu-
rious fa l s e - p o s i t i ves due to cross-contamination with other
microorganisms’ nucleic acid. PCR tests are often costly.
IX. SUSCEPTIBILITY TESTING
After a pathogen is cultured, its sensitivity to specific antibiotics serves
as a guide in choosing antimicrobial therapy. Some pathogens, such as
Streptococcus pyogenes and Neisseria meningitidis, usually have pre-
d i c t a ble sensitivity patterns to certain antibiotics. In contrast, most
gra m - n e g a t i ve bacilli, enterococci, and staphylococcal species show
unpredictable sensitivity patterns to various antibiotics, and require sus-
ceptibility testing to determine appropriate antimicrobial therapy.
A. Disk-diffusion method
The classic qualitative method to test susceptibility to antibiotics has
been the Kirby-Bauer disk-diffusion method, in which disks with
exact amounts of different antimicrobial agents are placed on cul-
ture dishes inoculated with the microorganism to be tested. The
organism’s growth (resistance to the drug) or lack of growth (sensi-
tivity to the drug) is then monitored (Figure 4.15). In addition, the
size of the zone of growth inhibition is influenced by the concentra-
tion and rate of diffusion of the antibiotic on the disk.
The disk-diffusion method is useful when sus-
ceptibility to an unusual antibiotic, not ava i l a bl e
in automated systems, is to be determ i n e d .
B. Minimal inhibitory concentration
Q u a n t i t a t i ve testing uses a dilution technique, in which tubes contain-
ing serial dilutions of an antibiotic are inoculated with the organism
whose sensitivity to that antibiotic is to be tested. The tubes are incu-
bated and later observed to determine the minimal inhibitory concen-
t ration (MIC) of the antibiotic necessary to prevent bacterial gr ow t h
(Figure 4.16). To provide effe c t i ve antimicrobial thera py, the clinically
o b t a i n a ble antibiotic concentration in body fluids should be gr e a t e r
than the MIC. Quantitative susceptibility testing may be necessary fo r
patients who either fail to respond to antimicrobial thera py, or who
relapse during thera py. In some clinical cases, the minimum bacteri c i-
dal concentration may need to be determined. This is the lowest con-
c e n t ration of antibiotic that kills 100 percent of the bacteria, ra t h e r
than simply inhibiting gr ow t h .
C. Bacteriostatic vs. bactericidal drugs
As noted above, antimicrobial drugs may be bacteriostatic or bacteri-
cidal. Bacteriostatic drugs arrest the gr owth and replication of bacte-
ria at serum levels achieva ble in the patient, thus limiting the spread
of infection while the body’s immune system attack s, immobilize s,
and eliminates the pathogens. If the drug is removed before the
i m mune system has scavenged the organisms, enough viable organ-
isms may remain to begin a second cycle of infection. For ex a m p l e,
Figure 4.17 shows a labora t o ry ex p e riment in which the gr owth of
b a c t e ria is arrested by the addition of a bacteriostatic agent. Note
that viable organisms remain, even in the presence of the bacteri o-
static drug. By contrast, addition of a bactericidal agent kills bacteri a ,
and the total number of viable organisms decreases. Although pra c t i-
cal, this classification may be too simplistic because it is possible fo r
an antibiotic to be bacteriostatic for one organism and bactericidal fo r
another (for ex a m p l e, chloramphenicol is bacteriostatic against gra m -
n e g a t i ve rods and bactericidal against pneumococci).
30 4. Diagnostic Microbiology IX. Susceptibility Testing 31
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32 4. Diagnostic Microbiology
Study Questions
Choose the ONE correct answer
4.1 Among 100 employees at a hospital , five were
infected with a particular pathogen. When the employ-
ees were tested for the presence of the pathogen, ten
individuals gave a positive response. Subsequent
evaluation by independent tests revealed that five of
ten were, in fact, infected and five were not. Which
one of the following best describes the original test?
A. High sensitivity, high specificity
B. High sensitivity, low specificity
C. Low sensitivity, high specificity
D. Low sensitivity, low specificity
E. Data do not allow a determination.
4.2 Chose the item that correctly matches the microorgan-
ism with an appropriate stain or preparation.
A. Mycobacterium tuberculosis — India ink
B. Fungi — KOH
C. Cryptococcus neoformans in cerebrospinal fluid —
Ziehl-Neelsen (classic acid-fast stain)
D. Chlamydia — Gram stain
E. Escherichia coli (gram-negative bacterium)—Crystal
violet followed by treatment with acetone.
4.3 Which one of the following media is most suitable for
identifying Neisseria gonorrhoeae in a cervical swab?
A. Sheep blood agar
B. Chocolate agar
C. MacConkey agar
D. T h a y e r - M a r t i n
medium
E. Hektoen enteric
agar
Correct answer = B. All infected individuals were
detected, but many false positives occurred.
Correct answer = B. Treatment with KOH dis-solves host cells and bacteria, allowing fungi tobe visualized. My. tuberculosis is stained bythe Ziehl-Neelsen stain (the classic acid-faststain). C. neoformans in cerebrospinal fluid isvisualized with India ink. Organisms that areintracellular, such as chlamydia, or that lack acell wall, such as mycoplasma or ureaplasma,are not readily detected by Gram stain. Mostbacteria stain purple with crystal violet andiodine. If the stained cells are then treated withacetone, gram-positive organisms retain thestain, whereas gram-negative species, such asE. coli, lose the stain, becoming colorless.Visualization of E. coli requires the addition ofthe counterstain safranin, which stains gram-negative bacteria pink or red.
Correct answer = D. Sheep blood agar sup-
ports the growth of most bacteria, both gram-
positive and gram-negative. Chocolate agar
provides the growth requirements for fastidi-
ous organisms such as H. influenzae or N .
g o n o r r h o e a e, as well as for most other less-
fastidious bacteria. MacConkey agar supports
most gram-negative rods, especial ly the
Enterobacteriaeceae, but inhibits growth of
gram-positive organisms and some fastidious
gram-negative bacteria, such as haemophilus
and neisseria species. Thayer-Martin medium,
which is composed of chocolate agar supple-
mented with several antibiotics, suppresses
the growth of nonpathogenic N e i s s e r i a a n d
other normal and abnormal flora, but permits
the growth of gonococcus. Hektoen enteric
agar is also a selective medium often used to
culture S a l m o n e l l a and S h i g e l l a s p e c i e s .“Well, now that you have it, you can
stop worrying about getting it”
04 Diagnostic Micro 5-30-06 6/8/06 9:20 AM Page 32
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