The document discusses diagnostic microbiology and the role of the clinical microbiology laboratory. The key responsibilities of the laboratory include testing specimens to identify microorganisms causing illness, providing antimicrobial susceptibility results, and advising physicians. Important techniques used in diagnosis include microscopy, culture, antigen detection methods like ELISA, and molecular methods like PCR. Proper specimen collection, transport, and processing are essential for accurate diagnostic testing.
2. • Introduction
• Diagnostic Medical Microbiology is concerned with the
etiologic diagnosis of infection.
• The job of the clinical microbiology laboratory include
• 1. to test specimens from patients for microorganisms that
are, or may be, a cause of the illness.
• 2. To provide information (when appropriate) about the in
vitro activity of antimicrobial drugs against the
microorganisms identified.
• 3. confirming a clinical diagnosis of infectious disease with a
bacterial etiology.
• 4. To advise the physician as well as process specimens.
3. 5. The clinical microbiologist should participate in
decisions regarding the microbiologic diagnostic
studies to be performed.
6. Advise on the type and timing of specimens to be
collected.
7. Mode of transportation and storage.
8. Above all, the clinical microbiology laboratory,
whenever appropriate, should provide an
interpretation of laboratory results.
4. Laboratory procedures used in the diagnosis of
infectious diseases in humans include the following:
-Morphologic identification of the agent in stains
specimens or tissues using light and electron
microscopy.
--culture isolation and identification of the agent.
-Detection of antigen from the agent by immunologic
assay ( Latex agglutination, EIA, ELIZA etc).
- PCR method (DNA/DNA, DNA/RNA hybridization).
-Antibody demonstration.
5. • Specimen Selection, Collection and Processing
A properly collected specimen is the single most
important step in the diagnosis of any disease. This
is because the results of diagnostic tests for
infectious diseases depend upon selection, timing,
and method of collection of specimens. The
specimen must be collected from the anatomical
site most likely to yield the agent at that particular
stage of illness. Besides, the specimen must be
handled in such a way that will favour the
organisms survival and growth.
6. • GENERAL RULES TO ALL SPECIMENS:
1.The quantity specimen must be adequate.
2.It should be representative of infectious process e.g,
sputum not saliva, swab from wound’s depth not
from surface.
3.Avoiding specimen contamination by using only
sterile containers and observing aseptic precautions.
4.Prompt transportation of specimen to the
laboratory and examination must be immediately.
5.Samples must be taken or collected before
administering drugs.
7. • Specimens obtained through operation require
special attention. Enough tissue must be obtained
for both histopathologic and microbiologic
examination. Histopathologic examination is used
to distinguish neoplastic from inflammatory lesions
and acute from chronic inflammations. The type of
inflammation present can guide the type of
microbiologic examination performed. If, for
example, a caseous granuloma is observed
histopathologically, microbiologic examination
should include cultures for mycobacteria and fungi.
8. • Microbiologic Examination and stains.
Microscopic examination of both stained and
unstained specimens is simple and inexpensive but
less sensitive when compare with culture for
detection of small numbers of bacteria.
Direct examination of specimens frequently
provides the most rapid indication of microbial
infection. A variety of microscopic, immunologic,
and hybridization techniques have been developed
for rapid diagnosis.
9. • Macroscopic Examination
1. Properly collect a stool specimen for parasitic
examination.
2. Correctly describe the consistency and type of
parasites found in the different consistencies.
3. Correctly determine the presence of fresh and/or
occult blood in a stool specimen.
• Microscopic Examination
1. Prepare and examine slides by the direct wet film
and iodine stained procedures.
2. State the advantages and disadvantages of direct
wet film evaluation.
10. • STAINING METHODS.
• Bacteria consist of clear protoplasmic matter,
differing but slightly in refractive index from the
medium in which they are growing. It is difficult to
view them using ordinary microscope, except
special methods of illumination are employed to
see them in the unstained condition. Staining
therefore is of primary importance for the
recognition of bacteria.
• Different staining methods are available in
microbiology laboratory, but the commonest
include Gram stain, Ziehl- Neelsen (ZN) stain,
Giemsa technique etc.
11. • GRAM STAIN:
• Gram staining is a very useful procedure in diagnostic
microbiology . It is used to identify organisms or
pathogens in specimens and cultures by their Gram
reaction, that is dividing all bacteria into two, either
Gram positive and Gram negative according to whether
or not the organisms resist decolourisation with
acetone alcohol or aniline oil after staining with a para-
rosaniline (primary) dye e.g. Crystal violet and
subsequent treatment with iodine. The Gram positive
bacteria resist decolouration and remain stained a dark
purple colour while the Gram negative bacteria are
decolourised, and then counterstained light pink by the
subsequent application of basic fulchin, safranine and
neutra red.
12. • PROCEDURE FOR GRAM STAIN.
Fix smear by gentle heat.
Cover with Crystal violet
Wash with water. Do no blot.
Cover with lugol’s iodine.
Wash with water.
Decolourise in acetone for 30 seconds with gentle
agitation
Wash with water.
Counterstain with safranine for 30 seconds.
Wash with water and allow to dry.
13. • ZEIHL-NEELSEN ACID FAST STAIN:
The Ziehl–Neelsen stain, also known as the acid-fast stain. It
is a special bacteriological stain used to identify acid-
fast organisms, mainly Mycobacteria. Mycobacterium
tuberculosis is the most important of this group because it is
responsible for tuberculosis (TB).
• Mechanism explanation
Initially, Carbol Fuchsin stains every cell
When they are destained with acid-alcohol, only non-acid-fast
bacteria get destained since they don't have a thick, waxy
lipid layer like acid-fast bacteria.
When counter stain is applied, non-acid-fast bacteria pick it
up and become blue when viewed under the microscope.
Acid-fast bacteria retains Carbol Fuchsin so they appear red.
14. PROCEDURE FOR ZEIHL-NEELSEN
Drop suspension onto slide
Air dry slide 10 minutes at 60 °C, heat-fix slide 10 minutes
at 90 °C
Flood slide with Carbol Fuchsin
Hold a flame beneath the slide until steam appears but do
not allow it to boil
Allow hot slide to sit for 3 to 5 minutes, rinse with tap
water
Flood slide with 3% hydrochloric acid in isopropyl alcohol
Allow to sit 1 minute, rinse with tap water
Flood slide with Methylene Blue
Allow to sit 1 minute, rinse with tap water
Blot dry
View under oil immersion lens
15. • Techniques
A compound binocular microscope equipped with
low-power (1OX), high-power (40X), and oil
immersion (1OOX) achromatic objectives, 10X wide-
field oculars, a mechanical stage, a substage
condenser, and a good light source is sufficient for
microscopic examination of specimens in
microbiology laboratory. For examination of wet-
mount preparations, a darkfield condenser or
condenser and objectives for phase contrast
increases image contrast. An exciter barrier filter,
darkfield condenser, and ultraviolet light source are
required for fluorescence microscopy.
16. • IMMUNOLOGI ASSAY:
The most frequently used techniques for immunologic
detection of microbial antigens in the laboratory
include, latex particle agglutination, coagglutination,
and enzyme-linked immunosorbent assay (ELISA).
• Mechanism
Antibody to a specific antigen is bound to latex particles
or to a heat-killed and treated protein A-rich strain
ofStaphylococcus aureus to produce agglutination.
There are several approaches to ELISA; the one most
frequently used for the detection of microbial antigens
uses an antigen-specific antibody that is fixed to a solid
phase, which may be a latex or metal bead or the inside
surface of a well in a plastic tray. Antigen present in the
specimen binds to the antibody.
17. Mechanism (Contd.)
The test is then completed by adding a second
antigen-specific antibody bound to an enzyme that
can react with a substrate to produce a colored
product. When the enzyme-conjugated antibody is
added, it binds to previously unbound antigenic
sites, and the antigen is, in effect, sandwiched
between the solid phase and the enzyme-
conjugated antibody. The reaction is completed by
adding the enzyme substrate.
18. • In agglutination test, inert particles (latex
beads or heat-killed S aureus Cowan 1 strain
with protein A) are coated with antibody to
any of a variety of antigens. Pls. read more.
19. • Genetic approach:
Genetic probes are based on the detection of unique
nucleotide sequences with the DNA or RNA of a
microorganism. Once such a unique nucleotide
sequence, which may represent a portion of a
virulence gene or of chromosomal DNA, is found, it is
isolated and inserted into a cloning vector (plasmid),
which is then transformed into Escherichia coli to
produce multiple copies of the probe. The sequence is
then reisolated from plasmids and labeled with an
isotope or substrate for diagnostic use. Hybridization
of the sequence with a complementary sequence of
DNA or RNA follows cleavage of the double-stranded
DNA of the microorganism in the specimen.
20. MOLECULAR TECHNIQUES:
The use of molecular technology in the diagnoses of
infectious diseases has been further enhanced by the
introduction of gene amplication techniques, such as
the polymerase chain reaction (PCR) in which DNA
polymerase is able to copy a strand of DNA by
elongating complementary strands of DNA that have
been initiated from a pair of closely spaced
oligonucleotide primers. This approach has had major
applications in the detection of infections due to
microorganisms that are difficult to culture (e.g. the
human immunodeficiency virus) or that have not as yet
been successfully cultured (e.g. the Whipple's disease
bacillus).
21. • Culture
In many instances, the cause of an infection is confirmed by
isolating and culturing microorganism either in artificial
media or in a living host. Bacteria (including mycobacteria
and mycoplasmas) and fungi are cultured in either liquid
(broth) or on solid (agar) artificial media. Liquid media
provide greater sensitivity for the isolation of small numbers
of microorganisms; however, identification of mixed cultures
growing in liquid media requires subculture onto solid media
so that isolated colonies can be processed separately for
identification. Growth in liquid media also cannot ordinarily
be quantitated. Solid media, although somewhat less
sensitive than liquid media, provide isolated colonies that
can be quantified if necessary and identified. Some genera
and species can be recognized on the basis of their colony
morphologies.
22. Culture (Contd.)
• In some instances one can take advantage of
differential carbohydrate fermentation capabilities
of microorganisms by incorporating one or more
carbohydrates in the medium along with a suitable
pH indicator. Such media are called differential
media (e.g., eosin methylene blue or MacConkey
agar) and are commonly used to isolate enteric
bacilli. Different genera of the Enterobacteriaceae
can then be presumptively identified by the color as
well as the morphology of colonies.
23. • Culture media can also be made selective by
incorporating compounds such as antimicrobial agents
that inhibit the indigenous flora while permitting
growth of specific microorganisms resistant to these
inhibitors. One such example is Thayer-Martin medium,
which is used to isolate Neisseria gonorrhoeae. This
medium contains vancomycin to inhibit Gram-positive
bacteria, colistin to inhibit most Gram-negative bacilli,
trimethoprim-sulfamethoxazole to
inhibit Proteus species and other species that are not
inhibited by colistin and anisomycin to inhibit fungi. The
pathogenic Neisseria species, N gonorrhoeae and N
meningitidis, are ordinarily resistant to the
concentrations of these antimicrobial agents in the
medium.
24. • The number of bacteria in specimens may be used
to define the presence of infection. For example,
there may be small numbers (≤ 103 CFU/ml) of
bacteria. The amount of growth on the agar is
then reported semiquantitatively as many,
moderate, or few (or 3+, 2+, or 1+ ), depending on
how far out from the inoculum site colonies
appear. An organism that grows in all streaked
areas would be reported as 3+.
25. • Chlamydiae and viruses are cultured in cell culture
systems, but virus isolation occasionally requires
inoculation into animals, such as suckling mice,
rabbits, guinea pigs, hamsters, or primates.
Rickettsiae may be isolated with some difficulty
and at some hazard to laboratory workers in
animals or embryonated eggs. For this reason,
rickettsial infection is usually diagnosed
serologically. Some viruses, such as the hepatitis
viruses, cannot be isolated in cell culture systems,
so that diagnosis of hepatitis virus infection is
based on the detection of hepatitis virus antigens
or antibodies.
26. • METHODS OF INCUBATION.
• Cultures are generally incubated at 35 to 37°C in an
atmosphere consisting of air, air supplemented with carbon
dioxide (3 to 10 percent), reduced oxygen (microaerophilic
conditions), or no oxygen (anaerobic conditions), depending
upon requirements of the microorganism. Since clinical
specimens from bacterial infections often contain aerobic,
facultative anaerobic, and anaerobic bacteria, such
specimens are usually inoculated into a variety of general
purpose, differential, and selective media, which are then
incubated under aerobic and anaerobic conditions.
• The duration of incubation of cultures also varies with the
growth characteristics of the microorganism. Most aerobic
and anaerobic bacteria will grow overnight, whereas some
mycobacteria require as many as 6 to 8 weeks.
27. • Microbial Identification
• Microbial growth in cultures is demonstrated by the
appearance of turbidity, gas formation, or discrete
colonies in broth; colonies on agar; cytopathic effects or
inclusions in cell cultures; or detection of genus- or
species-specific antigens or nucleotide sequences in the
specimen, culture medium, or cell culture system.
• Identification of bacteria (including mycobacteria) is based
on growth characteristics (such as the time required for
growth to appear or the atmosphere in which growth
occurs), colony and microscopic morphology, and
biochemical, physiologic, and, in some instances, antigenic
or nucleotide sequence characteristics. The selection and
number of tests for bacterial identification depend upon
the category of bacteria present (aerobic versus anaerobic,
Gram-positive versus Gram-negative, cocci versus bacilli)
and the expertise of the microbiologist examining the
culture.
28. • Gram-positive cocci that grow in air with or
without added CO2 may be identified by a
relatively small number of tests . The identification
of most Gram-negative bacilli is far more complex
and often requires panels of 20 tests for
determining biochemical and physiologic
characteristics. The identification of filamentous
fungi is based almost entirely on growth
characteristics and colony and microscopic
morphology. Identification of viruses is usually
based on characteristic cytopathic effects in
different cell cultures or on the detection of virus-
or species-specific antigens or nucleotide
sequences.
29. • Interpretation of Culture Results
• Some microorganisms, such as Shigella
dysenteriae, Mycobacterium tuberculosis, Coccidioides
immitis, and influenza virus, are always considered clinically
significant. Others that ordinarily are harmless components
of the indigenous flora of the skin and mucous membranes
or that are common in the environment may or may not be
clinically significant, depending on the specimen source
from which they are isolated. For example, coagulase-
negative staphylococci are normal inhabitants of the skin,
gastrointestinal tract, vagina, urethra, and the upper
respiratory tract (i.e., of the nose, oral cavity, and pharynx).
Therefore, their isolation from superficial ulcers, wounds,
and sputum cannot usually be interpreted as clinically
significant. They do, however, commonly cause infections
associated with intravascular devices and implanted
prosthetic materials.
30. • However, because intravascular devices penetrate the skin
and since cultures of an implanted prosthetic device can be
made only after incision, the role of coagulase-negative
staphylococci in causing infection can usually be surmised
only when the microorganism is isolated in large numbers
from the surface of an intravascular device, from each of
several sites surrounding an implanted prosthetic device, or,
in the case of prosthetic valve endocarditis, from several
separately collected blood samples. Another
example, Aspergillus fumigatus, is widely distributed in
nature, the hospital environment, and upper respiratory
tract of healthy people but may cause fatal pulmonary
infections in leukemia patients or in those who have
undergone bone marrow transplantation. The isolation of A
fumigatus from respiratory secretions is a nonspecific
finding, and a definitive diagnosis of invasive aspergillosis
requires histologic evidence of tissue invasion.
31. • Serodiagnosis
• Infection may be diagnosed by an antibody response
to the infecting microorganism. This approach is
especially useful when the suspected microbial agent
either cannot be isolated in culture by any known
method or can be isolated in culture only with great
difficulty. The diagnosis of hepatitis virus and Epstein-
Barr virus infections can be made only serologically,
since neither can be isolated in any known cell culture
system. Although human immunodeficiency virus type
1 (HIV-1) can be isolated in cell cultures, the technique
is demanding and requires special containment
facilities. HIV-1 infection is usually diagnosed by
detection of antibodies to the virus.
32. • Serodiagnosis(Contd.)
• The disadvantage of serology as a diagnostic tool is
that there is usually a lag between the onset of
infection and the development of antibodies to the
infecting microorganism. Although IgM antibodies
may appear relatively rapidly, it is usually necessary
to obtain acute- and convalescent-phase serum
samples to look for a rising titer of IgG antibodies to
the suspected pathogen. In some instances the
presence of a high antibody titer when the patient is
initially seen is diagnostic; often, however, the high
titer may reflect a past infection, and the current
infection may have an entirely different cause.
Another limitation on the use of serology as a
diagnostic tool is that immunosuppressed patients
may be unable to mount an antibody response.
33. • Antimicrobial Susceptibility
• The responsibility of the microbiology laboratory includes
not only microbial detection and isolation but also the
determination of microbial susceptibility to antimicrobial
agents. Many bacteria, in particular, have unpredictable
susceptibilities to antimicrobial agents, and their
susceptibilities can be measured in vitro to help guide the
selection of the most appropriate antimicrobial agent.
• Antimicrobial susceptibility tests are performed by
1. Disk Diffusion Method: In this method, a standardized
suspension of a particular microorganism is inoculated onto
an agar surface to which paper disks containing various
antimicrobial agents are applied. Following overnight
incubation, any zone diameters of inhibition about the disks
are measured and the results are reported as indicating
susceptibility or resistance of the microorganism to each
antimicrobial agent tested.
34. 2. Minimum Inhibitory Concentration (MIC): Is the
lowest concentration of antimicrobial agent
that inhibits the growth of the microorganism.
The MIC and the zone diameter of inhibition
are inversely correlated. In other words, the
more susceptible the microorganism is to the
antimicrobial agent, the lower the MIC and
the larger the zone of inhibition. Conversely,
the more resistant the microorganism, the
higher the MIC and the smaller the zone of
inhibition.
35. • The term susceptible means that the
microorganism is inhibited by a concentration of
antimicrobial agent that can be attained in blood
with the normally recommended dose of the
antimicrobial agent and implies that an infection
caused by this microorganism may be
appropriately treated with the antimicrobial agent.
The term resistant indicates that the
microorganism is resistant to concentrations of the
antimicrobial agent that can be attained with
normal doses and implies that an infection caused
by this microorganism could not be successfully
treated with this antimicrobial agent.
36. SUMMARY
• In summary, information provided by microscopic
techniques serves as a rapid presumptive diagnosis
of an infection e.g, pulmonary tuberculosis using Z-
N staining techniques, gram staining technique is
used to distinguish whether a micro organism
(bacteria) is either gram positive or gram negative, a
coccus or bacilus. Useful informations can also be
provided from the microscopical examination of
wet preparations e.g when looking for motile
vibrios in a feacal specimen or capsulated C
neoformans in csf.
37. SUMMARY (Contd).
Other diagnostic techniques i.e culture isolation and
identification of the agent, detection of antigen
from the agent by immunologic assay ( Latex
agglutination, EIA, ELIZA etc), PCR method
(DNA/DNA, DNA/RNA hybridization) and antibody
demonstration (serology).