Clinical Microbiology I Lecture Notes (LM 323) 2-10-2018 PDF

Summary

These lecture notes cover the fundamentals of clinical microbiology, focusing on bacterial cultivation techniques, nutritional needs, types of culture media, and the in vivo to in vitro transition. This document also contains useful information on bacterial isolation and identification.

Full Transcript

CLINICAL MICROBIOLOGY I

LM 323

Lecture no. (2)

2 -10 - 2018

Dr. Muhanmad Shakhatreh
Traditional Cultivation and Identification of Bacteria
Cultivation is the process of growing microorganisms in culture by taking bacteria
from the infection site (i.e., the in vivo environment) by some means of specimen
collection and growing them in the artificial environment of the laboratory (i.e., the in
vitro environment).
Various principles and methods are required for bacterial cultivation and identification.
Direct laboratory methods such as microscopy provide preliminary information about
the bacteria involved in an infection
Bacterial growth is usually required for definitive identification and characterization.
 PRINCIPLES OF BACTERIAL CULTIVATION
Bacterial cultivation has three main purposes:
To grow and isolate all bacteria present in a clinical specimen
To determine which of the bacteria that grow are most likely causing
infection and which are likely contaminants or colonizers
To obtain sufficient growth of clinically relevant bacteria to allow
identification and characterization
BACTERIAL CULTIVATION :
Once grown in culture, most bacterial populations are easily observed
without microscopy and are present in sufficient quantities to allow
laboratory identification procedures to be performed.
The successful transition from the in vivo to the in vitro environment
requires that the nutritional and environmental growth requirements of
bacterial pathogens be met.
 BACTERIAL CULTIVATION
The in vivo to in vitro transition is not necessarily easy for bacteria.
In vivo they are utilizing various complex metabolic and physiologic pathways
developed for survival on or within the human host.
Then, relatively suddenly, they are exposed to the artificial in vitro environment
of the laboratory.
The bacteria must adjust to survive and multiply in vitro:.
Their survival depends on the availability of essential nutrients and
appropriate environmental conditions
 Bacterial Isolation Techniques
Microbial cultures are mostly mixed:
Identification depend on isolating individual colonies
Testing requires pure cultures
Isolation technique provides an essential microbiological tool
Original inoculum containing a mixture of bacteria is spread into 4
quadrants on solid media.
To reduce the number of bacteria in each subsequent quadrant.
Colonies are masses of offspring from an individual cell therefore streaking
attempts to separate individual cells.
Discrete colonies form as the individual cells are separated and then
multiply to form isolated colonies in the later quadrants
 NUTRITIONAL REQUIREMENTS
Bacteria have numerous nutritional needs that include different gases, water, various
ions, nitrogen, sources for carbon, and energy.
General Concepts of Culture Media:
In the laboratory:
Nutrients are incorporated into culture media on or in which bacteria are grown.
If a culture medium meets a bacterial cell’s growth requirements, then that cell will
multiply to sufficient numbers to allow visualization by the unaided eye.
Bacterial growth after inoculation also requires that the medium be placed in optimal
environmental conditions.
Because different pathogenic bacteria have different nutritional needs, various types
of culture media have been developed for use in diagnostic microbiology.
For certain bacteria the needs are relatively complex, and exceptional media
components must be used for growth (bacteria with such requirements are said to be
fastidious).
Alternatively, the nutritional needs of most clinically important bacteria are relatively
basic and straightforward (non- fastidious bacteria).
 Phases of Growth Media
Growth media are used in either of two phases: liquid (broth) or solid (agar).
In some instances (e.g., certain blood culture methods), a biphasic medium that
contains both a liquid and a solid phase may be used.

In broth media, nutrients are dissolved in water, and bacterial growth is indicated
by a change in the broth’s appearance from clear to turbid (i.e., cloudy).
The turbidity, or cloudiness, of the broth is due to light deflected by bacteria present
in the culture
The more bacteria growth, the greater the turbidity.
At least 1,000,000 bacteria per milliliter of broth are needed for turbidity to be
detected with the unaided eye
 Bacterial Culture media:
Solid media are made by adding a solidifying agent to the nutrients and water.
Agarose, the most common solidifying agent, has the unique property of melting at
high temperatures (≥95° C) but re-solidifying only after its temperature falls below
50° C.
Addition of agar allows a solid medium to be prepared by heating to an extremely
high temperature, which is required for sterilization, and cooling to 55° to 60° C for
distribution into petri dishes.
On further cooling, the agarose-containing medium forms a stable solid gel referred
to as agar.
The petri dish containing the agar is referred to as the agar plate
Different agar media usually are identified according to the major nutritive
components of the medium (e.g., Sheep Blood Agar, bile esculin agar, xylose-
lysine-desoxycholate agar).
 Media culture:
With appropriate incubation conditions, each bacterial cell inoculated onto the agar
medium surface will proliferate to sufficiently large numbers to be observable with
the unaided eye

The resulting bacterial population is considered to be derived from a single bacterial cell
and is known as a colony.
All bacterial cells within a single colony are the same genus and species, having
identical genetic and phenotypic characteristics (i.e., are a single clone).
Bacterial cultures derived from a single colony or clone are considered “pure”
Pure Cultures are required for subsequent procedures used to identify and
characterize bacteria.
The ability to select pure (individual) colonies is one of the first and most important
steps required for bacterial identification and characterization.

Bacteria grow on solid media as colonies.
A colony is defined as a visible mass of
microorganisms all originating from a single
mother cell, therefore a colony constitutes a
clone of bacteria all genetically alike.
 Media Classifications and Functions
Media are categorized according to their function and use.
In diagnostic bacteriology there are four general categories of media:
Enrichment, supportive, selective, and differential.
Enrichment media contain specific nutrients required for the growth of
particular bacterial pathogens that may be present alone or with other
bacterial species in a patient specimen.
This media type is used to enhance the growth of a particular bacterial
Pathogen from a mixture of organisms by using nutrient specificity.
One example of such a medium is buffered charcoal-yeast extract agar,
which provides L-cysteine and other nutrients required for the growth of
Legionella pneumophila, the causative agent of legionnaires’ disease

Gram-negative bacterium

Legionnaires' disease
is a severe, often
lethal, form of
 Culture media:
Supportive media contain nutrients that support growth of most nonfastidious organisms
without giving any particular organism a growth advantage.
Selective media contain one or more agents that are inhibitory to all organisms
except those being sought.
These media select for the growth of certain bacteria to the disadvantage of others.
Inhibitory agents used for this purpose include dyes, bile salts, alcohols, acids, and
antibiotics.
An example of a selective medium is phenylethyl alcohol agar (PEA), which inhibits the
growth of aerobic and facultatively anaerobic gram-negative rods and allows gram
positive cocci to grow
 Bacterial Culture media:
Differential media employ some factor (or factors) that allows
colonies of one bacterial species or type to exhibit certain
metabolic or culture characteristics that can be used to
distinguish them from other bacteria growing on the same agar
plate.
One commonly used differential medium is MacConkey agar,
which differentiates between gram-negative bacteria that can
and cannot ferment the sugar lactose
 Culture media:
Many media used in diagnostic
bacteriology provide more than
one function.
For example, MacConkey agar is
both differential and selective
because it will not allow most
Gram-positive bacteria to grow.
Another example is sheep blood
agar (SBA).
This is the most commonly used
supportive medium for diagnostic
bacteriology because it allows
many organisms to grow. Blood agar is considered as nutritive and
differential media because it differentiates
between organisms based on hemolysis:
In many ways this agar is also
Beta hemolysis
differential because the
Alpha hemolysis
appearance of colonies produced
Gamma hemolysis
by certain bacterial species is
readily distinguishable
Sheep Blood Agar
 Isolation of bacteria from specimens
To enhance the growth:
Isolation, and selection of etiologic agents, specimen inoculum is usually spread over
the surface of plates in a standard pattern so that individual bacterial colonies are
obtained and semi quantitative analysis can be performed.
Individual bacterial colonies are obtained and semi-quantitative analysis can be
performed, using streaking technique, the relative numbers of organisms in the original
specimen can be estimated based on the growth of colonies past the original area of
inoculation.
The commonly used streaking technique for isolation of bacteria from clinical
specimens
Loop is the flipped over or flamed and quadrant two is struck by pulling the loop
through quadrant one of a few times and streaking the rest of the area.
The nichrome loop is then flamed again and quadrant three is streaking
the rest of the area.
Finally quadrant four is streaked by pulling the loop over the rest of the agar without
further flaming.
 Bacterial growth and isolation
A commonly used is streaking method:
Using this method, the relative numbers of organisms in the original
specimen can be estimated based on the growth of colonies past the
original area of inoculation.
To enhance isolation of bacterial colonies, the loop should be flamed for
sterilization between streaking each subsequent quadrant.
Streaking plates inoculated with a measured amount of specimen, such
as when a calibrated loop is used to quantify colony-forming units (CFUs)
in urine cultures, is accomplished by spreading the inoculum evenly over
the entire agar surface
This facilitates counting colonies by ensuring that individual bacterial cells
will be well separated over the agar surface.

Calibrated loop is used
that delivers a specific
amount of urine to the
media
Isolation of bacteria from specimens
Bacterial Isolation Techniques
 Bacterial Isolation:
Microorganisms occur in huge numbers.
Isolation of single species (pure culture) is based on diluting sample out to a point
where a single cell will give rise to a single colony
Using a sterile loop a portion of an isolated colony is taken and transferred to the
surface of a suitable enrichment medium that is then incubated under conditions
optimal for the organism.
When making transfers for subculture it is beneficial to flame the inoculating loop
between streaks to each area on the agar surface.
Subculturing refers to transferring microorganisms from one medium to another.
For example, bacteria growing in broth may be transferred to an agar plate.
This avoids over-inoculation of the subculture media and ensures individual
colonies will be obtained
(To enhance isolation of bacterial colonies, the loop should be flamed for sterilization
between streaking each subsequent quadrant).
Once a pure culture is available in a sufficient amount an inoculum for subsequent
identification procedures can be prepared
 Pure bacterial culture isolation:
In streaking method:
Microorganisms present in the specimen are successively diluted
out as each quadrant is streaked until finally each morphotype is
present as a single colony
Numbers of organisms present can subsequently be graded as:
4+ (many, heavy growth) if growth is out to the fourth quadrant,
3+(moderate growth) if growth is out to the third quadrant,
2+ (few or light growth) if growth is in the second quadrant,
1+ (rare) if growth is in the first quadrant.
This tells the clinician the relative numbers of different organisms
present in the specimen;
Such semiquantitative information is usually sufficient for the physician to
be able to treat the patient.
Pure culture isolation (streaking method)
 BACTERIAL CULTIVATION:
ISOLATION OF BACTERIA FROM SPECIMENS
The process of bacterial cultivation involves:
The use of optimal artificial media and incubation conditions to
isolate and identify the bacterial etiologies of an infection as
rapidly and as accurately as possible.
ISOLATION OF BACTERIA FROM SPECIMENS
Cultivation of bacteria from infections at various body sites is
accomplished by inoculating processed specimens directly onto
artificial media.
Incubation conditions are selected for media ability to support the
growth of the bacteria most likely to be involved in the infectious
process.
Infection: The invasion
and multiplication of
microorganisms such as
bacteria, viruses, and
parasites that are not
normally present within
the Human host body
 Evaluation of Colony Morphologies
Initial evaluation of colony morphologies on the primary plating media is extremely important.

Microbiologists can provide physicians with early preliminary information regarding the patient’s
culture results.

This information also is important for deciding which subsequent steps to take for definitive
organism identification and characterization.

Type of Media Supporting Bacterial Growth.

Different media are used to recover particular bacterial pathogens so that determining which
media support growth is a clue to the type of organism isolated (e.g., growth on MacConkey
agar indicates the organism is a Gram negative bacillus).
The incubation conditions that support growth may also be a preliminary indicator of which
bacteria have been isolated (e.g., aerobic vs. anaerobic bacteria).
Relative Quantities of Each Colony Type.

Establishing the Bacterial Clinical Significance depends on :

The predominance of a bacterial isolate is often used as one of the criteria,
Direct smear results
Microorganism virulence,
The body site from which the culture was obtained
 Colony Characteristics
Noting key features of a bacterial colony is important for any bacterial identification;
success or failure of subsequent identification procedures often depends on the
accuracy of these observations.
Criteria frequently used to characterize bacterial growth include the following:

Colony size (usually measured in millimeters or described in relative terms such as
pinpoint, small, medium, large)
Colony pigmentation
Colony shape (includes form, elevation, and margin of the colony
Colony surface appearance (e.g., glistening, opaque, dull, transparent)
Changes in agar media resulting from bacterial growth (e.g., hemolytic pattern on
blood agar, changes in color of pH indicators, pitting of the agar surface
Odor (certain bacteria produce distinct odors that can be helpful in preliminary
identification)
 Bacterial Colony Characteristics
Many of these criteria are somewhat subjective, and the adjectives and
descriptive terms used may vary among different laboratories.
Regardless of the terminology used, nearly every laboratory’s protocol for
bacterial identification begins with some agreed-upon colony description of
the commonly encountered pathogens.
Although careful determination of colony appearance is important, it
is unwise to place total confidence on colony morphology for
preliminary identification.
Bacteria of one species often exhibit colony characteristics that are nearly
indistinguishable from those of many other species.
Bacteria of the same species exhibit morphologic diversity
For example, certain colony characteristics may be typical of a given
species, but different strains of that species may have different morphologies.
 Gram stain and subculture:
The Gram stain and microscopic evaluation of cultured bacteria are used
with colony morphology to decide which identification steps are needed.
To avoid confusion, organisms from single colony are stained.
In many instances, staining must be performed with each different colony
morphology that is observed on the primary plate.
In other cases, staining may not be necessary because growth on a
particular selective agar provides dependable evidence of the organism’s
Gram stain morphology

Following characterization of growth on primary plating media all
subsequent procedures for definitive identification require the use of pure
cultures (i.e., Cultures containing one strain of a single species).

If sufficient inoculum for testing can be obtained from the primary media

Then a subculture is not necessary except as a precaution:
To obtain more of the etiologic agent if needed
To ensure that a pure inoculum has been used for subsequent tests (i.e., a
purity check).
 Classification Systems in the Prokaryotes
1. Macroscopic morphology – colony appearance
2. Microscopic morphology
3. Physiological / biochemical characteristics
4. Chemical analysis
5. Serological analysis
6. Genetic and molecular analysis
G + C base composition by assessing molecular guanine and
cytosine (GC) content
DNA analysis using genetic probes
Nucleic acid sequencing and rRNA analysis

The systematic classification and categorization of organisms into
ordered groups: are called taxonomy: The critical feature for all
Useful for: these classification systems is
an organism identified by one
individual (scientist, clinician,
Diagnostic microbiology epidemiologist), is recognized
as the same organism by
Studies in epidemiology and pathogenicity another individual.
The Gram stain, which divides most clinically significant bacteria into two
main groups, is the first step in bacterial identification
 PRINCIPLES OF IDENTIFICATION
Microbiologists use various methods to identify organisms (most clinically
relevant bacteria) cultivated from patient specimens.
Accurate bacterial identification is very significant because identity is
central to diagnostic bacteriology issues, including:
- Determining the clinical significance of a particular pathogen (e.g., is the
isolate a pathogen or a contaminant?)
- Guiding physician care of the patient
- Determining whether laboratory testing for detection of antimicrobial
resistance is warranted
- Determining the type of antimicrobial therapy that is appropriate
- Determining whether the antimicrobial susceptibility profiles are unusual
or aberrant for a particular bacterial species
- Determining whether the infecting organism is a risk for other patients in
the hospital, the public, or laboratory workers
 The identification of a bacterial isolate requires:
Analysis of information gathered from laboratory tests that provide
characteristic profiles of bacteria.
The tests and the order in which they are used for organism
identification are often referred to as an identification scheme.
Identification schemes can be classified into one of two categories:
(1) Those that are based on genotypic characteristics of bacteria
(2) Those that are based on phenotypic characteristics.
Certain schemes rely on both genotypic and phenotypic characteristics.
Some tests, such as the Gram stain, are an integral part of many schemes
used for identifying a wide variety of bacteria,
These schemes utilize the bacterial morphology and staining properties of
the organism, as well as O2 growth requirements of the species combined
with a variety of biochemical tests.
 ORGANISM IDENTIFICATION USING GENOTYPIC
CRITERIA
Genotypic identification methods involve characterization of some portion of a
bacterium’s genome Using molecular techniques for DNA or RNA analysis.
This usually involves detecting the presence of a gene, or a part thereof, or an RNA
product that is specific for a particular organism.
The presence of a specific gene or a particular nucleic acid sequence is interpreted as
a definitive identification of the organism.
The genotypic approach is highly specific and often very sensitive.
With the ever-expanding list of molecular techniques being developed, the genetic
approach to organism identification will continue to grow and become more integrated
into diagnostic microbiology laboratory protocols

Polymerase chain
reaction-restriction
fragment length
polymorphism
(PCR-RFLP)
 16S rRNA Gene Sequencing for Bacterial Identification
in the Diagnostic Microbiology Laboratory
PCR-amplified 16S-rRNA gene sequencing can be useful for straightforward
classification of purified isolates
The 16S rRNA gene, a molecular marker for identification of bacterial species:
16S ribosomal RNA (rRNA) sequencing is a common amplicon sequencing method
used to identify and compare bacteria present within a given sample.
16S rRNA gene sequencing is a well-established method for studying phylogeny and
taxonomy of samples from complex microbiomes or environments that are difficult or
impossible to study.
The use of 16S rRNA gene sequences to study bacterial phylogeny and taxonomy
has been by far the most common housekeeping genetic marker used for a
number of reasons.
These reasons include:
(i) Its presence in almost all bacteria, often existing as a multigene family,
or operons;
(ii) The function of the 16S rRNA gene over time has not changed,
suggesting that random sequence changes are a more accurate
measure of time (evolution)
(iii) The 16S rRNA gene (1,500 bp) is large enough for informatics purposes
Identification based on the 16S rRNA
gene is by no means: successful and
effective
 BACTERIAL IDENTIFICATION USING PHENOTYPIC
CRITERIA
Phenotypic criteria are based on observable physical or metabolic characteristics of bacteria, that
is, identification is through analysis of gene products rather than through the genes themselves.

The phenotypic approach is the classic approach to bacterial identification, and most identification
strategies are still based on bacterial phenotype.

Some characteristics may require subcellular analysis Involving sophisticated instrumentation (e.g.,
high-performance liquidhromatography [HPLC] to analyze cell wall components.

Other characterizations are based on the antigenic makeup of the organisms and involve
techniques based on antigen-antibody interactions
Most of the phenotypic characterizations used in diagnostic bacteriology are based on tests that
establish a bacterial isolate’s morphology and metabolic capabilities.

The most commonly used phenotypic criteria include:
Microscopic morphology and staining characteristics
Macroscopic (colony) morphology
Environmental requirements for growth
Resistance or susceptibility to antimicrobial agents
Nutritional requirements and metabolic capabilities
 Principles of Identification
Identification schemes or charts for final identification are found:
In most instances, identification schemes for final identification are based on the
cellular morphologies and staining characteristics of bacteria.
Bacterial identification schemes are based on:
Bacterial Cellular morphologies
Staining characteristics
Organism nutritional requirements
Organism metabolic capabilities
Abbreviated identification flowcharts for commonly encountered bacteria are found
This flowchart simply illustrates how information about microorganisms is integrated
into subsequent identification schemes that are usually based on the organism’s
nutritional requirements and metabolic capabilities
In certain cases Microscopic Morphology and staining characteristics alone are
enough to identify bacterial species
Example:
Using the fluorescent- labeled specific antibodies and fluorescent microscopy to
identify two bacteria: Legionella pneumophila and Bordetella pertussis

Gram-negative pathogen , and the
causative agent of pertussis or whooping cough.
 Microscopic Morphology and Staining
Characteristics
Microscopic evaluation of bacterial cellular morphology which is facilitated by the Gram stain or
Other enhancing methods provides the most basic and important information on which final
identification strategies are based

For this reason, a Gram stain of bacterial growth from isolated colonies on various media
is usually the first step in any identification scheme.

Based on these findings, most clinically relevant bacteria can be divided into four distinct groups:
Gram-positive cocci, Gram-negative cocci, Gram-positive bacilli, and Gram-negative bacilli
Some bacterial species are morphologically indistinct and are described as “Gram-negative
coccobacilli,” “Gram-variable bacilli,” or pleomorphic (i.e., exhibiting various shapes).
Still other morphologies include curved and/or rods and spirals.
Even without staining, examination of a wet preparation of bacterial colonies under oil immersion
(1000× magnification) can provide clues as to possible identity.
For example, a wet preparation prepared from a translucent, alpha-hemolytic colony on blood
agar may reveal cocci in chains, a strong indication that the bacteria are probably streptococci

“Gram-negative
example for Gram -ve coccoacilli: Hemophilus influenzae
coccobacilli,”
Bacterial Identification:
Examples of characteristics used as criteria for bacterial identification and classification