Chapter 16 - Introduction to Medical Microbiology PDF

Summary

This document is an introduction to medical microbiology. It outlines learning outcomes, compares prokaryotic and eukaryotic cells, and details methods for identifying various microbes, including bacteria, fungi, and parasites. The document also introduces concepts like primary culture, sterilization, and quality control in microbiology.

Full Transcript

Chapter 16
INTRODUCTION TO MEDICAL
MICROBIOLOGY

1
 Learning Outcomes
1. Name the four (4) distinctive fields of study in microbiology.
2. Compare a prokaryotic cell versus a eukaryotic cell.
3. When given an example, identify the genus and species of a
microorganism.
4. Define pathogen, nosocomial infection (HAI), and
opportunistic pathogen.
5. List the different methods of disinfection and sterilization in
the microbiology lab.
6. Explain the importance of collection requirements,
transportation, and specimens for microbiological
examination.
7. List the basic equipment and techniques used in microbiology.
8. Explain the principle of the Gram stain reaction for gram-
positive and gram-negative bacteria.
9. List the different morphological characteristics of bacteria.
10.Explain the dilution streak method for isolation of bacterial
colonies.

2
 Learning Outcomes
11. Define primary culture, subculture, and pure culture.
12. Define the terms aerobic and anaerobic.
13. List the classification of common media used in the
microbiology laboratory.
14. Identify the three (3) types of hemolysis used to classify
certain bacteria.
15. Define cystitis and pyelonephritis.
16. Explain the method used to streak and isolation
organisms in a urine culture.
17. Identify antimicrobial susceptibility tests from
photomicrographs shown.
18. Explain the different areas of quality control performed in
the microbiology laboratory.
19. Identify the characteristics of fungi.
20. List the common parasites and their sources as discussed
in the PowerPoint.

3
 Introduction to Microorganisms

https://youtu.be/9JW63U2mzqo?
si=VvrktOCiCEn9B4aP
The field of medical or clinical microbiology
involves the isolation and identification of
infectious organisms, and the development of
effective ways to eliminate or control infectious
organisms.
Medical microbiology is generally divided into
the study of bacteria, viruses, fungi, and
parasites.
The study of bacteria is bacteriology, the
study of fungi is mycology, the study of
parasites is parasitology, and the study of 4
 Introduction to
Microorganisms
All living organisms can be classified according to their
cellular makeup.

Cells are defined as prokaryotic or eukaryotic.

5
 Introduction to
Microorganisms

Prokaryotic and eukaryotic have cell
differences
Prokaryotes (Greek for “before nucleus”) do
not have a nucleus (membrane-bound organelle
containing chromosomes) or any other
membrane-bound organelles such as
mitochondria. For example: bacteria
Eukaryotes (Greek for “true nucleus”) are
organisms composed of eukaryotic cells and
include animals, plants, and fungi. For
example: parasites and fungi

6
Introduction to Microorganisms

Fig. 15.1. Major
features of
prokaryotic and
eukaryotic
cells. (From Murray
PR, Rosenthal KS,
Pfaller MA: Medical
microbiology, ed 5,
Philadelphia, 2005,
Mosby.)

7
 Classification of
Microorganisms:
Taxonomy
https://youtu.be/jet1l0g8unk?si=oiviGXzhlF_tcTXN
The scientific study of and the classification process is known as
taxonomy.
Provides an orderly method for placing organisms into categories.

Historically, categories were based on morphologic and biochemical
properties. Now genetic testing has provided a more detailed and
accurate method for classifying and grouping organisms.
Taxonomy is also used as a standard method for developing a
nomenclature of living things.
Taxonomy provides a mechanism for the ID of living things and assigning
them to a particular taxonomic gp, such as bacteria, protozoa, or fungi.

8
Classification of
Microorganisms:
Taxonomy
With the use of biological classification methods, it is possible
for the laboratory microbiologist to ID microbes systematically
through the use of:
A. Morphologic
B. Biochemical
C. Genetic characteristics
The classification scheme is divided into the following
categories: kingdom, phylum, class, order, family, genus, and
species.

There are five kingdoms within the classification scheme:
Animalia, Plantae, Protista, Fungi, and Monera (also referred to
as Prokaryotae).
◦ Bacteria belong to the kingdom Monera, parasites to the kingdom
Protista, and yeasts and molds to the kingdom Fungi.

9
Classification of
Microorganisms:
Taxonomy
Medically important microorganism include large groups
of microorganism, and the family division may be used to
include all members.

The family division precedes the genus designation; in
other words, similar genera are grouped into families.

10
 Classification of
Microorganisms: Taxonomy
As part of the systematic classification, all
organisms are designated with a minimum
of binomial nomenclature (consisting of 2
names). Binomial nomenclature consists of
the genus + species name.
One genus may have many different species.
◦ EXAMPLE: Staphylococcus aureus, Staphylococcus
epidermidis

Normal flora
◦ Microorganisms are present under normal conditions in specific
sites on or in the human body.
◦ In areas of the body with expected microbiota, host microbiota,
and the immune system interact to maintain tissue homeostasis
in healthy individuals.

11
 Classification of
Microorganisms: Taxonomy
Normally sterile fluids and their common
pathogens
Blood
◦ Staphylococcus aureus, Streptococcus pneumoniae,
Escherichia coli, Clostridium spp.
Cerebrospinal fluid
◦ Neisseria meningitidis
Urine
◦ E. coli, Proteus sp., Pseudomonas sp.
Sputum
◦ Streptococcus pneumoniae, Staphylococcus aureus
Stomach
◦ Helicobacter pylori

12
 Classification of
Microorganisms: Taxonomy
Anatomic body locations, normal flora, pathogens
Skin
◦ Normal flora: Staphylococcus sp. coagulase negative
◦ Pathogen: Staphylococcus aureus

Intestines
◦ Normal flora: Escherichia coli, Pseudomonas sp.
◦ Pathogen: Salmonella sp., Shigella sp.

Throat
◦ Normal flora: Alpha (α) streptococcus, commensal Neisseria sp.
◦ Pathogens: Group A-β hemolytic Streptococcus pyogenes

Genitourinary
◦ Normal flora: None
◦ Pathogens: Neisseria gonorrhoeae, Chlamydia trachomatis; In vaginitis-Gardnerella
vaginalis, Trichomonas vaginalis or Candida albicans

13
 Classification of
Microorganisms: Taxonomy
Pathogenic microorganisms
◦ Microorganisms that cause disease are pathogens.
◦ The ability to cause disease is pathogenicity.
◦ Healthcare-associated infections (HAIs) or nosocomial
infections are infections that patients acquire during
treatment in a healthcare facility such as MRSA.
◦ An opportunistic pathogen does not usually cause an
infectious disease in a person with an intact immune
system but can cause disease when the host’s immune
system has been compromised.
◦ https://youtu.be/JYRkXhT1XEs?si=nPHntpBgUaKE--8u

14
Protection of Laboratory Personnel,
Decontamination, Disinfection, and
Sterilization

Classification of biological agents based on
hazard to personnel
◦ Biosafety Level 1: minimal hazard (non-pathogenic strain ecoli)
◦ Biosafety Level 2: moderate threat (Salmonella, Shigella)
◦ Biosafety Level 3: not common in the laboratory (Yellow fever,
TB)
◦ Require personnel to have specialized training and use special barrier devices
◦ Biosafety Level 4: highest risk (EBOLA)
◦ Not found in routine laboratories, pose high risk of aerosol transmission,
are frequently fatal, and have no treatment or vaccine.
◦ CDC

◦ https://youtu.be/xNYASNEdgg8?si=F9LmgGAS_qVY6_5H

15
Protection of Laboratory Personnel,
Decontamination, Disinfection, and
Sterilization

General safety practices in the microbiology
laboratory
◦ Waste disposal process-
◦ use biohazardous bags/containers for culture media and
patient specimens
◦ use puncture-resistant sharps containers for needles
◦ The decontamination process is completed by autoclaving,
incineration, or burning.

◦ Disinfection process- disinfect lab benchtops before and after
using 10% bleach

16
Protection of Laboratory
Personnel,
Decontamination,
Disinfection, and
Sterilization
Incinerators and Flame
Burners:
Are used to sterilize
inoculating loops and needles
These units are electrical, as
opposed to flame burners that
operate on gas, and may still
be used in research or
teaching labs.

Now disposable loops are used

17
Protection of Laboratory
Personnel, Decontamination,
Disinfection, and Sterilization
Disinfection and Sterilization Techniques-
Essential to use sterile media for growing pure
cultures of bacteria and to avoid contamination
by microorganisms in nature (organisms in the
air, on the hands, and lab equipment and
supplies)
Contaminated media must be disposed of in
biohazard bags

18
Protection of Laboratory
Personnel, Decontamination,
Disinfection, and Sterilization
Types of Disinfection Techniques include
chemical
Disinfectants.

A. Sterilization-killing spores of bacteria
by involving physical means such as
heat or filtration and chemical means
such as oxidation
B. Disinfection: destroying bacteria by
physical means (dry heat) or
chemicals (bleach 10%, phenols,
aldehydes, and alcohols)
C. Antisepsis: includes iodine and alcohol
to disinfect the skin before drawing
blood or venipuncture.

19
Protection of Laboratory
Personnel, Decontamination,
Disinfection, and Sterilization
TYPES OF STERILIZATION TECHNIQUES:
A.USE OF HEAT OR BURNING BY
1. Sterilization by dry heat
2. Sterilization by moist heat- The most effective means
of sterilization with moist heat involves steam under
pressure, using a special device called an autoclave

20
Protection of Laboratory
Personnel, Decontamination,
Disinfection, and Sterilization
The USE OF FILTRATION:
1. Filtration through thin membrane filters may be used
as an alternate method of sterilization
2. Heat Sensitive solutions such as vaccines or antibiotic
solutions can be sterilized by filtration
3. HEPA filters, filter air in biological safety cabinets
( isolation and operating rooms use these) are capable of
removing 99% of microorganisms larger than 0.3 microns

21
Specimens for
Microbiological
Examination
Specimen collection requirements for
culture
◦ Documentation for all specimens sent to the microbiology
laboratory should include the source. If available, the
anatomic location of the wound is important and it is also
useful to indicate what antibiotics the patient may have
received.
◦ Identification of the causative agent is required to initiate
effective treatment.
◦ For each specimen, personnel collecting the specimen must
follow appropriate procedures and be aware of the types of
pathogens present in each type of specimen.

22
 Specimens for
Microbiological Examination
Specimen containers
◦ Specimens must be collected in sterile containers and must
not be contaminated during transfer to or isolation in the
laboratory.
◦ Disposable containers
◦ Disposable culture units
◦ Anaerobic/ Aerobic transport systems

23
 Specimens for
Microbiological Examination
◦ Transport to the laboratory
◦ Specimens should be delivered to the
laboratory promptly.
◦ Although many organisms remain viable for
long periods after collection, some are
fastidious, requiring special growth conditions,
including rapid inoculation into a suitable
nutrient medium.
◦ Some organisms are so fragile that the
appropriate collection device and nutrient
media are supplied to the patient so that the
specimen can be placed directly into the
container.

24
Specimens for
Microbiological
Examination
◦ Handling and storing specimens in the laboratory
◦ Immediate culture of freshly collected specimens is not always practical.
◦ Storage is not appropriate for some microorganisms
(certain meningitis-causing bacteria in CSF are
Susceptible to low temps)
◦ Refrigeration –will prevent overgrowth of normal flora in the specimen
◦ Refrigeration is not appropriate for some
microorganisms (anaerobic bacteria, CSF, genital
cultures for Neisseria, stay at RT)
◦ Freezing
◦ Serum samples for serology testing can be stored in
the freezer for 1 week before testing.
◦ Only when specimens are properly collected and handled are the final results
of the culture or test valid.

25
 Specimens for
Microbiological Examination
Types of microbiology specimens
collected
◦ Blood
◦ Body fluids
◦ Cerebrospinal fluid
◦ Inner ear
◦ Respiratory
◦ Scrapings
◦ Stool
◦ Sputum
◦ Swabs of various anatomical sites
◦ Urine

26
 Basic Equipment and
Techniques Used in
Microbiology
Most microbiology laboratory work
involves procedures to culture,
characterize, and identify various
microbes
◦ Culture of organisms present in the patient specimens
◦ Classification and identification of the isolated
organisms
◦ Interpretation of organism susceptibility patterns to
determine an appropriate antimicrobial agent

Inoculating needles or loop-were reusable
but are now disposable (leading to a
decrease in contamination)

27
Basic Equipment and
Techniques Used in
Microbiology
In microbiology, the main difference between solid and liquid media is
that solid media contains a solidifying agent, while liquid media does
not:
Solid media
Contains a solidifying agent like agar, gelatin, or silica gel. This allows for
the growth and isolation of individual colonies of microorganisms on the
surface of the media.Solid media is used to establish pure cultures,
isolate microbes, and make agar slants and agar stabs.
Liquid media
Also known as nutrient broths, these media are commonly used for
growing microorganisms. Liquid media can be prepared with a variety of
nutrient components, such as peptone, yeast extract, inorganic salts,
and distilled water.

28
 Basic Equipment and
Techniques Used in
Microbiology

Fig. 15.5. (A) Example of bacterial growth on a solid blood agar plate. (B) Turbidity produced by
bacteria growing in thioglycollate liquid broth. (From A. Mahon CR, Lehman DC, Manuselis:
Textbook of Diagnostic Microbiology, ed. 5, 2015.)

29
 Basic Equipment and
Techniques Used in
Microbiology

Culturing techniques
◦Dilution streak technique
◦ The first streak is continued across approximately one
quarter of the plate (first quadrant). The plate is then
shifted about a one-quarter turn and streaked again,
beginning at the periphery, overlapping the previously
inoculated area a few times, and continuing across the
second quadrant. The plate is turned once again and
streaked a third time, beginning at the periphery, drawing
the loop through the second streak a few times, and
continuing across the third quadrant. The fourth quadrant is
streaked beginning at the periphery, drawing the loop
through the third streak a few times, and continuing across
the fourth quadrant.

30
Basic Equipment and Techniques
Used in Microbiology

Fig. 15.6. Dilution streak
technique. (From Tille PM:
Bailey and Scott’s diagnostic
microbiology, ed 13, St Louis,
2014, Mosby.)

31
Basic Equipment and
Techniques Used in
Microbiology
Incubators:
A microbiology incubator is a heated, insulated chamber that
maintains the ideal conditions for growing and maintaining
microbiological cultures:
Temperature: The incubator maintains a specific temperature for
the growth of cells, which can vary depending on the organism. For
example, bacteria like E. coli and mammalian cells grow well at
around 99°F (37°C), while budding yeast grows best at 86°F (30°C).
Humidity: The incubator maintains the ideal humidity level for the
growth of cells.
Gas composition: The incubator maintains the ideal gas
composition for the growth of cells, such as the carbon dioxide
(CO2) and oxygen content.
Sterility: The incubator maintains a sterile environment for the
growth of cells.

32
 Identification of
Bacteria
The identification of most bacteria involves
microscopic observations (smear preparation and
staining), bacterial cultivation, and biochemical
tests.
A. Smear preparation and stains used in microbiology:
◦ Smear preparation: to visualize the presence of bacteria, the specimen
is spread thinly on a glass microscope slide and allowed to air dry.
◦ Staining procedures used (gram stain) yield valuable information like
the examination of cultures to determine purity. GS on CSF and BFs
were considered STAT results and had to be called (sterile fluids).
◦ Types of Stain: Differential stains use more than one stain to provide
additional information about bacteria. Cells from different bacterial
species can appear different based on their chemical or structural
properties.
◦ GPC stains purple and GNR stains pink
◦ Simple stains- methylene blue stain - used in microbiology to stain cells,
tissues, and other specimens to highlight their structures, shapes, and
locations. MANY OTHERS!

33
34
Identification of Bacteria
◦ Involves morphologic examination under the
microscope (BRIGHTFIELD MICROSCOPY)
◦ Morphology of bacteria:
◦ Spherical or round bacteria are cocci (singular
coccus)
◦ The prefix diplo- describes bacteria that occur in pairs, strepto-
describes bacteria occurring in chains, and staphylo- refers to
irregular clumps or clusters of bacterial cells.
◦ Rod-shaped bacteria are bacilli (singular bacillus)
◦ Curved rods are called vibrios
◦ Spiral-shaped bacteria are spirochetes and spirilla
(singular spirochete and spirillum).

35
Identification of
Bacteria
Fig. 15.9. Bacterial
morphology. Shown are
characteristic shapes and
cellular arrangements of
bacteria. (From Tille PM:
Bailey and Scott’s diagnostic
microbiology, ed 13, St
Louis, 2014, Mosby.)

36
 Identification of
Bacteria
The bacterial cultivation process of identification of
microorganisms begins by inoculating various nutrient
media designated to enhance the growth of the
pathogen bacteria.
◦Primary culture, subculture, and pure
culture
◦ When culturing specimens, the primary culture plates are
inoculated using the dilution streak technique to obtain isolated
colonies.
◦ If the colonies on the primary plates appear as mixtures of more
than one species of bacteria, a subculture (secondary streak
plate) must be performed to separate the different types of
bacteria.
◦ The growth of several colonies originating from a single colony, and
thus a single cell, is known as a pure culture.

37
Identification
of Bacteria
T Y PE S O F C U LT U R E M E D IA -
A G A R PLAT E S , A G A R
S LA N T S , B R O T H S (LI Q U ID
M E D IA )

Colony characteristics (appearance)
of bacterial cultures: when
inoculated and with proper temp
and moisture bacteria rapidly
multiply and form macroscopic
colonies.

38
Identification of
Bacteria

Fig. 15.11. Pure culture of
Staphylococcus aureus on a sheep
blood agar plate. Each colony began
as an individual
parent bacterial cell that multiplied
many times to become
visible. (From Tille PM: Bailey and
Scott’s diagnostic microbiology, ed
13, St Louis, 2014, Mosby.)

39
IDENTIFICATION OF
BACTERIA
Requirements for bacterial cultivation involve specific
requirements to sustain life and reproduce. The culture
requirements for bacteria include a source of nutrients,
proper temp, an adequate supply of oxygen, and the
correct pH.
For example, Oxygen requirements for Aerobes and
anaerobes
◦ Aerobes = grow with oxygen
◦ Anaerobes = grow without oxygen

◦ Nutrients- different bacteria require various types of
nutrients for energy production and metabolism. For
example, some grow on media containing simple
mixtures of inorganic salts.

40
 Identification of
Bacteria
◦ Temperature- bacteria grow at a wide range of temps
(35C)
◦ pH (hydrogen ion concentration)- culture medium
must contain proper nutrients in correct
concentrations but must also have the correct degree
of acidity or alkalinity. Most bacteria like media with a
pH between 6.5 to 7.5
◦ Sterile conditions- culture media must be sterile
◦ Moisture- necessary for metabolic reactions,
dehydration= reduces bacterial growth.

41
Identification of Bacteria
◦Incubation time and temperature for
routine cultures:
◦ Bacterial growth on artificial media or in culture
typically requires 24 to 48 hours, although anaerobic
cultures require longer incubation times, usually 3 to
5 days, to reach sufficient growth required for the
identification of the bacteria.

42
 Identification of
Bacteria
◦Storage of media- under refrigeration
4C to prevent deterioration and
dehydration

43
Identification of Bacteria
◦ Different types of media are used in micro to aid
not only in supporting growth but also in
identification. Therefore, media are placed in
categories according to their specific use:
◦ Classification of media
◦ Enrichment media- one bacteria grows in the presence of specific
nutrients
◦ Supportive media- water and nutrients that support the growth of
microorganisms (THIO broth)
◦ Selective media –inhibit the growth of gram-positive bacteria

◦ Differential media- It differentiates between microorganisms based on
their biochemical properties by incorporating specific chemicals or
indicators that react differently depending on the organism's
metabolism. (For example, MAC diff bacteria on the ability to ferment
lactose, NLF, and F)

44
 Identification of Bacteria- Selective
Media- LF Ecoli, NLF pseudomonas

Fig. 15.14. MacConkey agar (MAC). MAC is a selective and differential medium used frequently
for primary plating of specimens to isolate and differentiate gram-negative bacilli. (A) Gram-
negative bacilli that ferment lactose will appear pink/red. (B) Gram-negative bacilli that do not
ferment lactose will appear clear or slightly pink. (From Tille PM: Bailey and Scott’s diagnostic
microbiology, ed 13, St Louis, 2014, Mosby.)

45
 Identification of
Bacteria
◦Various types of media:
◦Chocolate agar (Choc)- fastidious bacteria
like Haemophilus and Neisseria
◦Hektoen enteric agar (HE)- Salmonella,
Shigella
◦MacConkey agar (MAC)- GN bacteria
◦Sheep blood agar (BAP)- supports growth of
most bacteria
◦Thayer-Martin agar (modified Thayer-Martin
agar)-gonorrhea

46
 Identification of Bacteria

Fig. 15.15. Hektoen enteric (HE) agar. HE agar is a selective and differential medium for the isolation
of enteric pathogens. (A) Escherichia coli is a lactose-fermenting gram-negative bacillus and appears
yellow on HE. (B) Shigella spp. do not ferment lactose and will appear green or transparent. (C)
Salmonella spp. are also non–lactose-fermenters but produce hydrogen sulfide (H 2S); therefore the
colonies will appear green or transparent with black centers. (From Tille PM: Bailey and Scott’s
diagnostic microbiology, ed 13, St Louis, 2014, Mosby.)

47
Identification of Bacteria-Lysine
Iron Agar

LIA is used to
distinguish bacteria
that can produce
hydrogen sulfide and
decarboxylate lysine
from those that
cannot. It's especially
useful for
distinguishing Gram-
negative bacilli,
particularly those in
the
Enterobacteriaceae 48
Identification of Bacteria- BAP
(blood agar plate)

Fig. 15.17. Three
characteristic types of
hemolysis on sheep blood
agar: (A) Alpha hemolysis of
Streptococcus pneumoniae,
(B) Beta hemolysis of
Staphylococcus aureus, and
(C) Gamma hemolysis of
Enterococcus faecalis. (From
Tille PM: Bailey and Scott’s
diagnostic microbiology, ed
13, St Louis, 2014.)

49
Quality Control of Media
Quality control of media in microbiology is a
process to ensure that the media used in a
laboratory is of good quality and can produce
accurate results. This is important because the
quality of the media directly affects the
observations and conclusions drawn from the
microorganisms.

50
Identification of Bacteria
Biochemical or enzymatic tests- Many
bacteria can't be ID based on
microscopic or culture characteristics
alone.
◦ In multi-test systems, conventional biochemical tests are
arranged in a series.
◦ Bile esculin agar-
◦ Aids in the identification of enterococci
◦ Bile solubility test-
◦ Aids in the identification of S. pneumoniae
◦ Catalase test-
◦ Often used to differentiate staphylococci from
streptococci
51
Identification of Bacteria
◦ Citrate utilization
◦ Useful in the identification of members of the
Enterobacteriaceae
◦ Coagulase test
◦ Used to differentiate S. aureus from other members of
the genus Staphylococcus
◦ Indole test: Used to differentiate swarming Proteus
species and as a presumptive identification of E. coli

https://youtu.be/MYAl0mCSBxw?si=oTUVtNEA14_cCZMt

52
 Identification of
Bacteria

An API test panel, or Analytical Profile Index test panel,
is a set of biochemical test strips that identify bacteria and
fungi:
How it works: Each strip contains a series of cupules
with freeze-dried reagents and color indicators. A sample
containing the microbe is inoculated into the cupules, and
the strips are incubated. The results generate a code that
53
can be used to identify the microbe in a database.
 Urine Cultures
Cultures are done on urine to diagnose
bacterial infections of the urinary tract.
Urinary tract infections (UTIs) are of two
main types:
◦ Lower UTIs of the bladder or urethra, such as
cystitis
◦ Upper UTIs of the ureters and kidneys, such as
pyelonephritis

54
 Urine Cultures
Collecting the specimen
◦Interpretive guidelines for urine
specimens
◦ Type of specimen-UV or UC
◦ Number of potential pathogens->100 CFU of ECOLI
◦ Number of colony-forming units per milliliter
◦ A complete workup includes identification of the
organism and appropriate susceptibility testing
◦ Three or more organism types with none
predominating from a clean-catch midstream
specimen or catheterized specimen suggest
contamination; ask for another specimen.

55
 Urine Cultures
Methods for detection of urinary
tract infections
◦Rapid-screening test strips- Rapid-
screening test strips, also known as
urine dipsticks, are a common method
for detecting urinary tract infections
(UTIs) by analyzing a urine sample for
the presence of substances like
leukocytes (white blood cells) and
nitrites, which are often elevated in
individuals with a UTI

56
Urine Cultures
Quantitative culture methods are used in
clinical microbiology laboratories to
determine the bacterial burden in a
sample and whether it's clinically
significant.
The streak plate method is a
microbiology technique that
separates pure colonies of bacteria
from a mixed population. It's based
on the principle of dilution and is
used to isolate individual cells so
they can be counted as colony-
forming units (CFUs).

57
Urine Specimens
Gram stain of urine specimens (not routinely done):
A Gram stain of urine is a test that helps identify bacteria
in a urine sample to diagnose a bacterial infection:
How it works
A purple stain is used to color bacteria in a sample. The
bacteria will either retain the purple color (Gram-positive)
or turn pink (Gram-negative).
What it shows
The Gram stain groups bacteria by color and shape to
help determine the type of bacteria causing an infection

58
59
 Urine Cultures
Fig. 15.21. Method for
inserting a calibrated loop
into urine to ensure that
the proper amount of
specimen will adhere to
the loop. (From Tille PM:
Bailey and Scott’s
diagnostic microbiology,
ed 13, St Louis, 2014,
Mosby.)

60
Urine Cultures

Fig. 15.22. Method for streaking a
loopful of urine with a calibrated loop to
produce isolated colonies and
countable colony-forming units of
organisms.
(From Tille PM: Bailey and Scott’s
diagnostic microbiology, ed 13, St Louis,
2014, Mosby.)

61
 Throat Cultures

Collecting the specimen
Methods for detection of group A β-
hemolytic streptococci
◦ Rapid detection methods: Non-culture techniques
◦ Culture on sheep blood agar- addition of bacitracin disc (Taxo
A)
◦ Interpreting results of throat culture plates-colony
morphology & hemolysis on BAP
◦ Appearance of hemolysis- alpha, beta, gamma
◦ Identification of group A β-hemolytic streptococci
◦ Molecular diagnostic testing for streptococci-PCR
For detection of gp A or B (DNA)
62
Beta-hemolysis: Complete lysis of red blood cells around the
colony
Alpha-hemolysis: Partial lysis of red blood cells, also known as
"greening"
Gamma-hemolysis: No hemolysis

63
 Blood Cultures

Blood is normally sterile.

64
Blood Cultures- bacteria
isolated from blood
Staphylococci: Coagulase-negative staphylococci are the most frequently
isolated bacteria from blood cultures. Staphylococcus aureus is also
common.
Enterococci: Enterococcus faecalis and Enterococcus faecium are common
isolates.
Escherichia coli: A common isolate.

Klebsiella pneumoniae: A common isolate.

Streptococcus pneumoniae: A common isolate.

Pseudomonas aeruginosa: A common isolate.

Enterobacter cloaca: A gram-negative rod that is often isolated.

Salmonella typhi: A gram-negative rod that is often isolated.

Acinetobacter baumannii: A gram-negative rod that is often isolated

65
Blood Cultures
Collecting the specimen
◦ Cleansing the collection site- 70% alcohol and a povidone-iodine
solution

Culture media for blood- Here are some common types of blood
culture media:
Broth media: These media support the growth of bacteria and
some fungi. Some examples include tryptic soy broth, brain heart
infusion broth, and thioglycolate broth.
Columbia broth: This broth is good for anaerobic bacteria.
Pre-reduced peptone broths: These broths are good for
anaerobic bacteria.
Thio broths: These broths are good for anaerobic bacteria.

66
 Examination of Bldc’s
Blood cultures are laboratory tests that use Bactec media to detect the presence of bacteria, fungi,
viruses, and other germs in a blood sample:

Bactec media

A range of media that can detect aerobes, anaerobes, yeast, fungi, and mycobacteria.

Detection methods

Different Bactec systems use different methods to detect growth, including pressure changes, color
changes, and fluorescence.

Radiometric method

A method that measures the amount of 14CO2 produced by bacteria metabolizing 14C labeled palmitic
acid in the culture's liquid media.

Time to detection

The BACTEC system can detect growth faster than other systems, such as the BacT/Alert system.

Incubation time

If no growth is detected, the blood culture bottles may be incubated for up to two weeks.

67
Automated System for Blood cultures

68
Antimicrobial Susceptibility Tests
Antimicrobial susceptibility tests (ASTs) are medical tests that determine which antibiotics or other antimicrobial agents are most effective against a specific
microorganism causing an infection. ASTs are performed by clinical microbiology laboratories and are used to help physicians select the appropriate treatment for a
patient.

ASTs are important because:

Identify the specific diagnosis

ASTs help identify the specific diagnosis and the causative agent of the disease.

Target the appropriate treatment

ASTs help ensure that patients receive the appropriate treatment, as the same causative organism can have different resistance patterns.

Address antimicrobial resistance

AST results are an important component in addressing the problem of antimicrobial resistance.

There are several types of ASTs, including:

Broth microdilution: A widely used testing method

Rapid automated instrument methods: Use commercially marketed materials and devices

Disk diffusion: A manual method that uses filter paper disks to diffuse antimicrobials

Gradient diffusion: A manual method

69
Antimicrobial Susceptibility Tests

Fig. 15.26. Agar disk diffusion. (A) Mueller-Hinton agar has been inoculated with the test organism, and the
antibiotic disks have been added to the media. No incubation has yet occurred. (B) After 16 to 18 hours
incubation, the zones of inhibition are apparent. The zones of inhibition are measured and compared to a
table of values for each antibiotic. (From Tille PM: Bailey and Scott’s diagnostic microbiology, ed 13, St Louis,
2014, Mosby.)

70
Antimicrobial Susceptibility Tests
Antimicrobial susceptibility test results are usually reported as susceptible, intermediate, or
resistant:

Susceptible

The antibiotic was effective in killing or stopping the growth of the bacteria or fungus. This is the
preferred treatment option.

Intermediate

The antibiotic may be effective at a higher dose or more frequently. It may also only be effective
in certain parts of the body.

Resistant

The antibiotic was not effective in killing or stopping the growth of the bacteria or fungus. This is
not a good treatment option.

The results are based on the minimum inhibitory concentration (MIC), which is the lowest
concentration of an antibiotic that will stop the growth of bacteria. The laboratory will usually
include an interpretation of the results in addition to the MIC.

71
72
 Quality Control in the
Microbiology Laboratory
Quality control (QC) in a microbiology laboratory ensures the
accuracy of test results and the reliability of equipment, media,
reagents, and specimens:
Equipment: Equipment should be consistent each time it's
used. Laboratories should calibrate and maintain equipment and
ensure it's clean and sterile.
Media: Culture media should be tested for sterility and
performance.
Reagents: Chemicals should be sterilized to prevent
contamination.
Specimens: Specimens should be collected, transported, and
processed properly.
Antimicrobial tests: Laboratories should perform antimicrobial
susceptibility testing accurately. This includes reviewing the profile
for each organism tested before reporting results.

73
 Tests for Fungi
(Mycology)
Fungi are yeasts and molds.
Characteristics of fungi
◦ Fungi are eukaryotes, possessing a true nucleus with a
nuclear membrane and mitochondria, whereas bacteria
are prokaryotes, lacking these structures.
◦ Fungal cell walls are not composed of peptidoglycan
found in bacterial cell walls, but contain alternate
carbohydrates such as chitin.
◦ Yeasts are single-celled organisms that reproduce by
budding.
◦ Molds have a basic structure that consists of tube-like
filamentous projections called hyphae. Hyphae
continue to grow, forming an intertwined mass
collectively known as mycelia (singular mycelium).
74
 Tests for Fungi
(Mycology)

Fig. 15.27. Pseudohyphae consisting of
elongated cells with constrictions at
attachment sites. (From Mahon CR, Lehman
DC, Manuselis: Textbook of Diagnostic
Microbiology, ed. 5, 2015.)

75
 Tests for Fungi
(Mycology)
Tests for fungi can include:

Microscopic examination

A sample is examined under a microscope, sometimes with a stain or preparation. This can be enough to determine if a fungus is
causing an infection.

Fungal culture

A sample is sent to a lab to grow and identify the fungus. This is the primary test for diagnosing fungal infections. However, it
can take several weeks for some fungi to grow.

Susceptibility testing

A follow-up test to a fungal culture that helps determine how sensitive the fungus is to specific antifungal medications.

Antigen and antibody tests

Available for some fungi, but only for deep or systemic infections. These tests can be performed on blood or other bodily fluids.

MALDI-TOF

A rapid sample analysis technique that can identify fungi in minutes.

The type of sample collected depends on where the infection is suspected to be. For example, a fungal skin infection might be
diagnosed with a skin scraping, hair sample, or nail clipping. A fungal infection in another part of the body might be diagnosed
with a sample of blood, urine, sputum, vaginal secretions, or cerebrospinal fluid.

76
Tests for fungi
The India ink preparation and the germ tube test are both laboratory
methods used to identify fungi:
India ink preparation
A negative staining technique that detects the capsule of encapsulated fungi,
such as Cryptococcus neoformans. The capsule repels the India ink, which
appears as a halo around the yeast cell. This test is quick and inexpensive,
but it's not very sensitive and can be negative in up to half of cases of
cryptococcal meningoencephalitis.
Germ tube test
A rapid screening test that identifies Candida albicans by its production of
germ tubes. The germ tube is a straight-sided extension of the yeast cell
that's about half the width and three to four times the length of the cell. The
test involves inoculating fetal bovine serum with the yeast isolate and
incubating it at 35–37° C for 2.5–3 hours. Some species, like Candida
tropicalis, may form pseudohyphae instead of germ tubes, which can lead to
false positives.

77
 Tests for Fungi
(Mycology)

Fig. 15.28. Gram stain of yeast. Note: Yeast are not classified as gram positive because of absorption of Gentian
Violet stain. (From de la Maza LM, Pezzlo MT, Baron EJ: Color atlas of diagnostic microbiology, St Louis, 1997,
Mosby.)

78
 Tests for Parasites
(Parasitology)

Parasites live in or on their hosts, at
the expense of the host.
◦ Some parasites cannot survive without their designated
host.
◦ Other parasites can exist in a free-living state as an
intermediate state before transmission to a suitable host.
◦ Still others live commensally, a situation in which the
parasite and the host exist together with no harm coming
to the host; the relationship is beneficial to both.

Parasites as source of infection
◦ As a result of increased travel to tropical areas, and
because of the great influx of refugee populations, many
organisms endemic elsewhere are being identified in
patients in the United States.

79
 Tests for Parasites
(Parasitology)

Collection of specimens for parasite
identification
◦ Stool specimens-A stool exam, also known as an ova and
parasite (O&P) test, is a common way to identify parasites in
the digestive tract
◦ Blood specimens-making thin/thick smears-Thick blood
smears are more effective at detecting parasites because
they examine a larger sample of blood. Thin blood smears
help identify the species of parasite causing the infection. For
example: babesia

Methods for detection of parasites
◦ Wet mount, direct smear-Parasites have distinct shapes,
sizes, and internal structures (PINWORM test)
◦ PCR can detect the DNA or RNA of parasites in stool samples

80
 Tests for Parasites
(Parasitology)
Common parasites identified
◦ Trichomonas vaginalis
◦ T. vaginalis can inhabit the urogenital system of both males and females.
◦ It is considered a pathogenic parasite; T. vaginalis is the cause of vaginitis,
urethritis, and prostatitis.

Rapid antigen test: A quick test that can be performed at a
provider's office and usually produces results in under 15
minutes
Culture test: A sample is sent to a lab where cells grow for
up to a week, and then examined under a microscope
Nucleic acid amplification testing (NAAT): A laboratory
method that identifies the parasite's genetic material

81
 Tests for Parasites
(Parasitology)

Fig. 15.34. Trichomonas vaginalis trophozoite. (From Tille PM: Bailey and Scott’s diagnostic
microbiology, ed 13, St Louis, 2014, Mosby.)

82
 Tests for Parasites
(Parasitology)

Fig. 15.36. Cellophane tape preparation of Enterobius vermicularis (pinworm) eggs. (From
Tille PM: Bailey and Scott’s diagnostic microbiology, ed 13, St Louis, 2014, Mosby.)

83
Additional Point-of-Care
Rapid Testing
Applications
Rapid testing for streptococcal infections
Rapid testing for pneumococcus and legionellae
Rapid for plasmodium falciparum—falciparum malaria
(parasites)

84
Automation
MALDI-TOF (Matrix-Assisted Laser Desorption/Ionization
Time-of-Flight) mass spectrometry is a technique that
measures the mass of molecules in a sample. It's used in
many fields, including:
Microbiology: MALDI-TOF MS is a common tool for
identifying bacteria, fungi, and other microbes in clinical
laboratories. It's faster, more accurate, and less
expensive than traditional biochemical identification
methods.

85