Introduction to Medicine Cultivation and Normal Flora PDF

Summary

This document provides an introduction to medicine cultivation and normal flora. It covers topics such as bacterial genetics, methods of genetic exchange (transformation, transduction, conjugation), and essential components and types of culture media, including their uses.

Full Transcript

Bacterial Genetics

Bacterial genetic material
Is single circular DNA
Bacteria are haploid (have a single chromosome).
Bacteria has extra chromosomal genetic material called
plasmid.
Plasmid has different function:
 Contain genes that code for antibiotic resistance.
 Contain genes that code for extracellular toxin.
 For recombination of genetic material.

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Exchange of genetic information

involve a unilateral transfer of genetic information from a
donor cell to a receptor cell
The transfer of genetic information can occur by either of
the three methods:
 Transformation

 Transduction

 Conjugation
Transformation

A process by which a bacterium acquire DNA fragments
or genes from surroundings.
Usually this occurs in microbial culture.

Fig. Transformation process in bacteria
Transduction

is a method of gene transfer in which a virus (phage)
acts as a vehicle for carrying DNA from a donor
bacterium to recipient bacterium.
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Conjugation
A process where by DNA is transferred from one bacterium to
another by cell to cell physical contact using sex pili
Plasmids are the genetic elements most frequently transferred
by conjugation.

NB: Conjugation is seen frequently in Gram-. negative rods (Enterobacteriaceae)
 Cultivation of
microorganisms

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 Culture media are artificially prepared media containing
the required nutrients used for propagation of micro
organisms.
Once the bacteria are grown we can:
 Identify them either by presumptive lab diagnosis like
Gram stain or by definitive lab diagnosis like biochemical
test
 Test the antimicrobial sensitivity of the bacteria (drug
testing). This helps to know whether the bacteria are
sensitive or resistant to known antimicrobial drugs.

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 Common ingredients of culture media

1. H2O: is essential for growth of micro-organism and 80% of
bacterial cell is H2O.
 It must be free of mineral salts which can inhibit bacterial
growth.
 Either distilled or deionised water should be used.

2. Peptone: contains water soluble products obtained from
break down of animal or plant protein (contains free amino
acids, peptides, and proteoses (large sized peptides).
Eg. lean meat, heart meat, milk etc.
 Its the main source of nitrogen, some vitamins, carbohydrates,
nucleic acid fraction and minerals.
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3. Meat extract : this provides amino acids, minerals, and
essential growth factors.
4. Yeast extract : is a very good growth stimulant.
 It provides amino acids, water soluble vitamins (vit.B),
inorganic slats, and etc.
5. Mineral salts: are essential for growth & for metabolism
of living organism.
E.g;- SO4: as a source of sulphur
 PO42- :as a source of phosphorus
 Nacl: is the common ingredient and source of Na & Cl
 Other trace elements include Mg, Mn, etc
6. Carbohydrates : simple and complex sugars are used:
As energy and carbon source.
For differentiation of bacteria.
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8. Accessory growth factors
 Include vit B (thiamine, niacin, and biotin).These provide
the necessary condition for growth
9. Other ingredients include, blood, serum, egg yolk etc
depending on the organisms need.
7. Solidifying agents: are agents which are used to
solidify the culture media.
A. Agar : is a commonly used solidifying agent of culture
media.
 Is a mixture of two poly saccharide - agarose (70 -75%) &
agaropectin (20- 25%).
 It is produced from sea weeds
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 Agar is a good solidifying agent due to:
1. The protein is inert & undegradable by microorganism
2. Solid to gel transformation temperature is very high
i.e it solidifies at 45oC and changed to gel > 45oC
3. It can form gel (solidify) at 1.5% w/v concentration and
4. It forms semi solid gel at 0.4 – 0.5% w/v concentration

Uses of agar
5. Solidify culture media
6. Provide calcium and organic ions for the bacteria
7. Used for adding heat sensitive ingredients such as blood and
serum while the agar is in gel phase at 45–50oC
8. The agar is very transparent so that growth of colonies is
easily visible.
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Types of culture media

The main types of culture media are:
1. Basic media
2. Enriched
3. Selective media
4. Indicator (differential) media
5. Transport media

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1. Basic Media

These are simple media that will support the growth of
micro organisms that do not have special nutritional
requirements.
Example - Nutrient Agar
- Nutrient broth

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2. Enriched/Enrichment media

These media are required for growth of organism with
extra nutritional requirements such as H. influenza,
Neisseria spp, and some streptococcus species.
The media can be enriched with whole blood, lyzed
blood, serum, vitamins, and other growth factors.
E.g:- Blood Agar (contain whole blood)
- Chocolate agar (contain lyzed blood)
Enrichment media: this term is usually applied to fluid
selective media E.g. Tryptosoya broth, Selenite F broth

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3. Selective media

These are solid media which contain substances which
inhibit the growth of one organism to allow the growth of
the other to be more clearly demonstrated.
The medium is made selective by incorporation of certain
inhibitory substances like bile salt, crystal violet,
antibiotics, etc.
E.g. Addition of crystal violet favors the growth of gram
negative bacteria and slows the growth of Gram positives.
Selective medium is used when culturing a specimen
form a site having normal microbial flora to prevent
unwanted contaminants overgrowing a pathogen.
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Examples of Selective agar
1. Thiosulphate citrate bile salt sucrose agar(TCBS)
 is alkaline medium and selective for V. cholera.
2. Xylose Lysine Deoxy Cholate (XLD) agar
 selective for Salmonella and Shigella.
3. Modified New York City (MNYC) medium
 Selective for Neisseria gonorrhoeae.
4. Butzler medium
 Selective for Campylobacter species.
5. Salmonella and Shigella agar (SSA)
 Selective for Salmonella and Shigella species.

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5. Differential (Indicator) media

These are media to which dyes or other substances are
added to differentiate micro-organisms.
Many differential media distinguish between bacteria by
incorporating an indicator which changes colour when
acid is produced following fermentation of a specific
carbohydrate.
 E.g. Mac Ckonkey agar - contain neutral red as an indicator and
lactose as carbohydrate. Lactose fermenting bacteria will
become pink and other bacteria become colourless.

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 Figure: differential media (Triple sugar iron/TSI agar media)

Figure: differential media (MacConkey agar media , pink colonies are
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 6. Transport media

These are mostly semisolid media that contain ingredients to
prevent the overgrowth of commensals and ensure the
survival of aerobic & anaerobic pathogens when specimens
cannot be cultured immediately after collection.
Their use is particularly important when transporting
microbiological specimens form health centres to the district
microbiological laboratory or regional public health laboratory
Example
 Cary-Blair medium :– is used for preserving and transporting
enteric pathogens.
 Amies transport medium:- is used for transportation of
gonococci.
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Culture media can be classified by their consistency (form)
as:
A. Solid media
 Are solidified by agar
 Are used mainly in Petri dishes as plate cultures, in bottles or tubes as stab
(deeps) or slope cultures.
B. Semi solid media
 Are culture media prepared by adding small amount of agar
 Semi solid media are used mainly as transport media, and for motility
and biochemical tests.
C. Fluid culture media
 Fluid media are most commonly used as enrichment when organisms
are likely to be few
E.g. blood culture

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CULTURING OF BACTERIA

Materials for Culturing Bacteria
Basic materials used for culturing bacteria.
Culture media
Petri dishes
Test tubes
Inoculating loops, straight wire loops
Bunsen burner
Incubator

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Appearance of Bacterial colonies on solid Media
Bacterial colonies should be examined in a good light & a
low power magnifying lens can help to see morphological
details.
1. When viewed form above: colonies may appear round,
irregular crenated, or branching.
They may be transparent or opaque and their surface may
be smooth or rough, dull or shiny. Eg. The colonies of
pneumococci have a ringed appearance.

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2. When viewed form the side: Colonies may appear flat or
raised in varying degrees some times with beveled
edges or with a central elevation or depression.

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3. When touched with wire loop: Some colonies are soft and
easily emulsified such as S.aureus. Where as others are
difficult to break up such as S. pyogens.
4. The colour of colonies: this also helps to identify bacteria,
especially when using differential media containing
indicators.
E.g. - V. cholera in TCBS agar appear Yellow
- Corny bacterium diphteriae in Tellurite agar appear black.

Figure:TCBS Agar - Vibrio chol.

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Changes which may occur in the medium when bacteria are
cultured on solid agar.
These include hemolytic reactions, pigment production, color
changes surrounding carbohydrate fermenting colonies, &
blackening due to hydrogen sulphide production
 An example of pigment forming organism is pseudomonas
aeroginosa which produces a yellow – green color in media
such as blood agar and MacConkey agar.
 An examples of organism that produces a color change is Vibrio
chorera which is sucrose fermenting, giving a yellow color in
TCBS agar.

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 Blacking due to hydrogen sulphide production is seen with
many Salmonella cultured in kligler iron agar(KIA).
Hemolytic reaction in blood agar is seen with beta
hemolytic Streptococci (complete hemolysis) and alpha
hemolytic pneumococci(partial hemolysis)

Figure: Beta hemolysis Figure: Alpha hemolysis

NB. Morphological appearance of colonies on blood agar can vary
depending on the species of blood used.
E.g. Horse, sheep, or goat blood.
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Reporting culture results
The manner of reporting culture depends on whether the
specimen is either from a sterile site or from site with a
normal microbial flora.
Sites normally Sterile:
Identify and report all bacteria isolated up to their genera.
And if helpful identify the actual species using bio
chemical tests.
Sterile sites include blood, bone marrow, CSF, pleural
and peritoneal fluids.

NB. For isolating organism from sterile sites use culture media which is
non selective, and enriched.

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Sites Having a Microbial Flora:
Interpretation requires patients’ clinical data to judge
whether an isolate is a pathogen which causes the
patients illness.
Sites with normal flora include faeces (stool), sputum,
skin, throat and nose swabs, vagainal, cervical, and
urethral swabs.
NB: For isolating organism from sites with normal flora
selective media are much better than general media.

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NORMAL FLORA

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 The term "normal microbial flora" denotes the
population of microorganisms that inhabit the
skin and mucous membranes of healthy normal
persons.
Viruses and parasites are not considered
members of the normal microbial flora by most
investigators because they are not commensals
and do not aid the host.

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 The skin and mucous membranes always harbor a
variety of microorganisms that can be arranged into
two groups:
1. The resident flora consists of relatively fixed types
of microorganisms regularly found in a given area at a
given age; if disturbed, it promptly reestablishes
itself.
2. The transient flora consists of non-pathogenic or
potentially pathogenic microorganisms that inhabit the
skin or mucous membranes for hours, days, or weeks;
 it is derived from the environment, and does not establish itself
permanently on the surface.
Members of the transient flora are generally of little
significance as long as the normal resident flora
remains intact.
However, if the resident flora is disturbed, transient
microorganisms may colonize, proliferate, and 33
FIGURE: Numbers of bacteria that colonize different parts of the body.
Numbers represent the number of organisms per gram of homogenized
tissue or fluid or per square centimeter of skin surface.
NB: The human body, which contains about 1013 cells, routinely harbors
about 1014 bacteria
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Significance of the Normal Flora

Can cause infection
 When misplaced, e.g., fecal flora to urinary tract or
abdominal cavity, or skin flora to catheter
 if person becomes immunocompromised, normal flora
may overgrow (e.g. oral thrush).
Contributes to health
 Protective host defense
Produce antimicrobial substances against pathogens

Compete for attachment and nutrient with

pathogenic bacteria
 Serve as nutritional resource by synthesizing: vitamin K
& B.
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Normal Flora of the Skin
Because of its constant exposure to and contact with the
environment, the skin is particularly apt to contain transient
microorganisms.
Nevertheless, there is a constant and well-defined resident
flora, modified in different anatomic areas by secretions,
habitual wearing of clothing, or proximity to mucous
membranes (mouth, nose, and perineal areas).
The predominant resident microorganisms of the skin are:
 aerobic & anaerobic diphtheroid bacilli (eg, corynebacterium,
propionibacterium);
 Non-hemolytic aerobic & anaerobic staphylococci
(Staphylococcus epidermidis & other coagulase-negative
staphylococci, occasionally S aureus, & Peptostreptococcus spp);
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 Gram-positive, aerobic, spore-forming bacilli that are
ubiquitous in air, water, and soil;
alpha-hemolytic streptococci (viridans streptococci) and
enterococci (Enterococcus species); and
gram-negative coliform bacilli and acinetobacter.
Fungi and yeasts are often present in skin folds;
acid-fast, nonpathogenic mycobacteria occur in areas
rich in sebaceous secretions (genitalia, external ear).

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 Among the factors that may be important in eliminating
non-resident microorganisms from the skin are the
 low pH, the fatty acids in sebaceous secretions, and
 the presence of lysozyme.
Neither profuse sweating nor washing and bathing can
eliminate or significantly modify the normal resident flora.
Placement of an occlusive dressing on skin tends to
result in a large increase in the total microbial population
and may also produce qualitative alterations in the flora.

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 Normal Flora of the Mouth & Upper
Respiratory Tract
The flora of the nose consists of prominent corynebacteria,
staphylococci (S. epidermidis, S. aureus), and streptococci.
The mucous membranes of the mouth and pharynx are
often sterile at birth but may be contaminated by passage
through the birth canal.
 Within 4–12 hours after birth, viridans streptococci become
established as the most prominent members of the resident
flora and remain so for life. They probably originate in the
respiratory tracts of the mother and attendants.

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 Early in life, aerobic and anaerobic staphylococci, gram-
negative diplococci (neisseriae, Moraxella catarrhalis),
diphtheroids, and occasional lactobacilli are added.
When teeth begin to erupt, the anaerobic spirochetes,
Prevotella species, Fusobacterium species, Rothia
species, Capnocytophaga species establish themselves,
along with some anaerobic vibrios and lactobacilli.
Actinomyces species are normally present in tonsillar
tissue and on the gingivae in adults, and
various protozoa may also be present.
Yeasts (Candida species) occur in the adult mouth.

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 Small bronchi and alveoli are normally sterile.
The predominant organisms in the upper respiratory
tract, particularly the pharynx, are
 non-hemolytic and alpha-hemolytic streptococci and
neisseriae.
 Staphylococci, diphtheroids, haemophili, pneumococci,
mycoplasmas, and prevotellae are also encountered.

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 Infections of the mouth and respiratory tract are usually
caused by mixed oronasal flora, including anaerobes.
Periodontal infections, perioral abscesses, sinusitis, and
mastoiditis may involve predominantly
 Prevotella melaninogenica, fusobacteria, &
peptostreptococci.
Aspiration of saliva (containing up to 102 of these
organisms and aerobes) may result in necrotizing
pneumonia, lung abscess, and empyema.

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Normal Flora of the Intestinal Tract

At birth the intestine is sterile, but organisms are soon
introduced with food.
In breast-fed children, the intestine contains large
numbers of lactic acid streptococci and lactobacilli.
These aerobic and anaerobic, gram-positive, non-motile
organisms (eg, Bifidobacterium species) produce acid
from carbohydrates and tolerate pH 5.0.

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 In bottle-fed children, a more mixed flora exists in the
bowel, and lactobacilli are less prominent. As food habits
develop toward the adult pattern, the bowel flora
changes.
Diet has a marked influence on the relative composition
of the intestinal and fecal flora.
Bowels of newborns in intensive care nurseries tend to
be colonized by Enterobacteriaceae, eg, klebsiella,
citrobacter, and enterobacter.

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 In the normal adult, the esophagus contains
microorganisms arriving with saliva and food.
The stomach's acidity keeps the number of
microorganisms at a minimum (103–105/g of contents).
The normal acid pH of the stomach markedly protects
against infection with some enteric pathogens, eg,
cholera.
As the pH of intestinal contents becomes alkaline, the
resident flora gradually increases.

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 In the normal adult colon, 96–99% of the resident
bacterial flora consists of anaerobes:
 Bacteroides species, especially B fragilis; Fusobacterium
species; anaerobic lactobacilli, eg, bifidobacteria;
clostridia (C perfringens, 103–105/g); and anaerobic gram-
positive cocci (Peptostreptococcus species).
Only 1–4% are facultative aerobes
 gram-negative coliform bacteria, enterococci, and small
numbers of proteus, pseudomonads, lactobacilli, candida,
and other organisms.

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 Intestinal bacteria are important in
 synthesis of vitamin K,
 conversion of bile pigments and bile acids,
 absorption of nutrients and breakdown products, and
 antagonism to microbial pathogens.
Among aerobic coliform bacteria, only a few serotypes
persist in the colon for prolonged periods, and most
serotypes of Escherichia coli are present only over a
period of a few days.

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Normal Flora of the Urethra

The anterior urethra of both sexes contains small
numbers of the same types of organisms found on the
skin and perineum.
These organisms regularly appear in normal voided urine
in numbers of 102–104/mL.

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Normal Flora of the Vagina

Soon after birth, aerobic lactobacilli appear in the vagina
and persist as long as the pH remains acid (several
weeks).
 Mixed flora of cocci and bacilli
At puberty, aerobic and anaerobic lactobacilli reappear in
large numbers and
 contribute to the maintenance of acid pH through the production
of acid from carbohydrates, particularly glycogen.
 This appears to be an important mechanism in preventing the
establishment of other, possibly harmful microorganisms in the
vagina.

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 If lactobacilli are suppressed by the administration of
antimicrobial drugs,
 yeasts or various bacteria increase in numbers and cause
irritation and inflammation
After menopause, lactobacilli again diminish in number
and a mixed flora returns.
The normal vaginal flora includes group B streptococci in
as many as 25% of women of childbearing age.
 During the birth process, a baby can acquire group B
streptococci, which subsequently may cause neonatal
sepsis and meningitis.

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 The normal vaginal flora often includes also
 alpha hemolytic streptococci, anaerobic streptococci
(peptostreptococci), Prevotella species, clostridia,
Gardnerella vaginalis, Ureaplasma urealyticum, and
sometimes listeria or Mobiluncus species.
The cervical mucus has antibacterial activity and
contains lysozyme.

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Normal Flora of the Conjunctiva

The predominant organisms of the conjunctiva are
diphtheroids, S epidermidis, and non-hemolytic
streptococci.
Neisseriae and gram-negative bacilli resembling
haemophili (Moraxella species) are also frequently
present.
The conjunctival flora is normally held in check by the
flow of tears, which contain antibacterial lysozyme.

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Normal flora of the external auditory meatus

It is an extension of skin normal flora and often profusely
colonized.
 Staphylococcus epidermidis
 Diphtheroids
 Alpha-hemolytic and non-hemolyic streptococci
N.B there is no normal flora in blood and CSF

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DISINFECTION , DECONTAMINATION
AND STERILIZATION

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 Disinfection: Destruction of microbes that cause
disease; may not be effective in killing spores.
Antisepsis: destruction or inhibition of micro-organisms
in living tissue there by limiting or preventing harmful
effect of infection
Sterilization: is the destruction or complete removal of
all forms of micro-organisms including their spores.

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 The agents, which are used for sterilization and
disinfection, can be divided into two broad groups:
I. Chemical means’s of sterilization & disinfection
II. Physical means’s of sterilization & disinfection

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 Classification of Chemical Mean’s of
Sterilization and Disinfection

1. Chemical agents that damage the cell membrane
 Surface Active Agents
 Phenols
 Organic solvents.
2. Chemical agents that denature proteins
 Acids and Alkalis
3. Chemical agents that modify functional groups of
proteins and nucleic acids
 Heavy metals
 Oxidizing agents
 Dyes
 Alkylating agents
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1. Chemical Agents that Damage the cell
Membrane
1.1 Surface Active Agents
A. Cationic agents
Quaternary ammonium compounds (Quates)
 It causes loss of cell membrane semi permeability leading
to loss of nutrients and essential metabolites
B. Anionic agents
Soaps and fatty acids
 It causes gross disruption of cell membrane lipoprotein
framework.
 More active in Gram-positive bacteria than in Gram-
negative bacteria.
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Chemical Agents that Damage the cell Membrane
cont….
1.2. Phenolic Compounds
 Phenol is highly effective in Gram positive bacteria..
1.3. Organic Solvents
Alcohol e.g. Ethyl alcohol, Isopropyl alcohol
 Disorganize cell membrane lipid structure.
 Denatures protein.
 Active against Gram-positive bacteria, Gram-negative
bacteria and Acid fast bacilli.
Uses:
 Potent skin disinfectants
 Disinfects equipment's like clinical thermometer

N.B: Ethanol is potent at concentration of 70%
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2. Chemical Agents that Denature Proteins

E.g. Acids and alkalies, Quates, Alcohol
Causes conformational alteration of proteins.
Acids like benzoic acid, citric acid and acetic acid are
helpful as food preservatives: extending storage life of
food products.

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3. Chemical agents that modify functional groups
of proteins and nucleic acids

3.1 Heavy metals
Various metals and metal salts are commonly employed
to prevent microbial growth or kill microbes
Mercury compounds

e.g. mercuric chloride- limited use because of its toxicity.
- It can be used as antiseptics.

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 Silver compounds
e.g. Silver nitrate,
Used as ophthalmic and wound (e.g. in burn patients)
antiseptic.
3.2 Oxidizing Agents
Converts functional-S-H group into non-functional-S-S
group.
e.g. -Halogens like Chlorine and iodine
- Hydrogen peroxide

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Uses:
Hypochlorite: sanitizing agent in dairy and food
processing industries, households and hospitals.
Organic or inorganic chloramines: Is effective water
disinfectant acting by liberating chlorine.
Iodine: effective skin disinfectant.
Hydrogen peroxide (3-6%): Used for cleansing of wound,
disinfecting medical-surgical devices and plastic contact
lenses.

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3.3 Dyes
Example:
Malachite green
Brilliant green
Crystal violet/gentian violet

Uses:
Highly selective for Gram-positive bacteria.
For treatment of dermatological lesions.
For formulation of selective culture media.

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3.4 Alkylating Agents
A. Formaldehyde
- Formaldehyde 37% aqueous solution is named as Formalin.
Uses:
 Preservation of fresh tissues.
 Preparation of vaccines from bacterial surfaces, viruses & toxins

B. Glutaraldehyde
 Is ten times more effective than formaldehyde
 Used for sterilizing medical -surgical instruments

C. Ethylene oxide
is gaseous sterilizing chemical.

Use:
 Used to sterilize medical-surgical devices that would be damaged by
heat.
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II. Physical means of sterilization & disinfection

Physical means of sterilization and disinfection include
Heat, Filtration and Radiation

1. Heat: is the most reliable and universally applicable
method of sterilization.
Mechanism of Action:
Dry heat-denatures protein.
Moist heat-denatures and coagulates protein.

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1.1. Dry heat

It is less efficient and requires high temperature and long
period heating than moist heat.
A. Incineration
It is anefficient method of sterilization and disposal of
contaminated needles, syringes and cover slips at high
temperature.
B. Flaming
Inoculating wires, loops and points of forceps are
sterilized by holding them in the flame of a Bunsen
burner until they are red hot.
Scalpels , neck of flasks, bottles and tubes are exposed
for a few seconds, but it is of uncertain efficacy. 67
C. Hot air sterilizer (hot air oven/ dry oven)
It is essential that hot air should circulate between the
objects being sterilized. These must be loosely packed
and adequate air space to ensure optimum heat transfer.
It is done by applying 140-160 0C for 45 to 60 min or 180
0
C for 30 minutes.
Use:
Usually used to sterilize glass wares and metallic objects.

68
1.2. Moist heat
It is preferred to dry heat due to more rapid killing action.
Moist heat can be used by the following methods.

Temperature below 100 0c
This includes the method of pasteurization where objects are
subjected to a temperature of 72.oC for 15 seconds. This
method does not destroy spores.
- Pasturization: it is the process of application of heat at the
temperature of 620c for 30 minutes or 720c for 15 seconds
followed by rapid cooling to discourage bacterial growth.
Uses:
Pasteurization of milk ( disinfecting milk)
Preparation of bacterial vaccines.

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 Temperatures around 100oC

A. Boiling- (Hot water boilers) -are still a common methods
in many hospitals. the maximum temperature is 100oC and
will there for, not kill all the spores, but for 20 minute
exposure all vegetative forms of bacteria and viruses can
be destroyed provided instruments are cleaned before
putting them in boilers.
B. Tyndallization: Intermittent steaming
Steaming of the material is done at 1000c for 30 minutes for
three consecutive days.
The principle is that spores which survived the heating
process would germinate before the next thermal exposure
and then would be killed.
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Temperature above 100oC
Autoclave: Steam under pressure
It is based on the principle that when microorganism is
boiled at increased pressure (in closed container), hot
saturated steam will be formed which penetrates and
gives up its latent heat when it condenses on objects.
- Hot saturated stem in autoclaving acts as an excellent
agent for sterilization because of:
- High temperature
- Wealth of latent heat (stem under pressure)
- It destroys bacterial endospores and vegetative cells
Uses:
Sterilize solid and fluid culture media, gowns, medical
and surgical equipment. 71
Temperature gauge

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Table: Time-Temperature-Pressure Level Relationship in moist
heat sterilization (Autoclaving)
Temperature Time Pressure level

1210c 15 minutes 15 lb/inch2
1260c 10 minutes 20 lb/inch2
1340c 3 minutes 30 lb/inch2

N.B: Most autoclave work by 1210c ,15 minutes and 15 lb/inch2 (temperature,
time and pressure respectively).

73
Other methods using low temperature

A. Freezing (At 0oC or less temp)- is inactivation of living
bacteria by cold.
- It prevents active multiplication of bacteria by decreasing
the metabolic activity of bacteria.
B. Lyophilization: (Freeze-drying) is a process which
involves rapid freezing with subsequent drying.
Use:
Preservation of microbial cultures.
Preservation of vaccines.

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2. Filtration
Mechanical sieving through membrane filters.
Used in Sterilization of thermolabile parental and ophthalmic
solutions, sera and plasma.
Have no microbicidal nature.

Figure: Micropore filter apparatus 75
3. Radiation

Ionizing and ultra violet radiation.
 Ionizing radiation includes χ ray, γ ray and β ray.
These induce break down of single stranded or
sometimes double stranded DNA.
ultra violet radiation is less active than ionizing radiation

Uses of radiation:
Sterilize surgical sutures, catheters, Petri dishes, and
pharmaceutical products like hormones, enzymes and
antibiotics.

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LABORATORY DIAGNOSIS OF BACTERIAL
INFECTION

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Laboratory Diagnosis of Bacterial
Infection
Diagnosis requires a composite of information, including history,
physical examination, radiographic findings, and laboratory
examination.
Infections may be caused by bacteria, viruses, fungi, and
parasites.
The pathogen may be exogenous (acquired from environmental
or animal sources or from other persons) or endogenous (from
the normal flora).

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Laboratory Diagnosis of Bacterial Infection is used for
Identification of causative agent
Treatment: accurate antimicrobial treatment
Surveillance purpose: to asses burden of disease in the community
Outbreak investigation

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Specimen Selection, Collection, and
Processing

Specimens are selected based on the type of underlying infection.
Contamination of the specimen must be avoided by using only
sterile equipment and aseptic precautions.
The specimen must be taken to the laboratory and examined
promptly.
Special transport media may be helpful.
Specimens must be collected before antimicrobial drugs are
administered.

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Clinical samples

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Microbial Examination

A) Direct Examination :
 Direct examination of specimens reveals gross
pathology.
 Direct examination can be.

I) Macroscopic examination
 Visual examination of specimen for color, consistency,
presence or absence of blood/mucus.

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Microbial Examination…
II) Microscopic examination
Is examination using magnifying lenses.
This might include microscopic examination of wet mount
preparation or stained preparation.
Wet mount preparation
 Is direct smear examination by adding normal saline under 10x, & 40x objectives
of microscope.
Staining
 Is application of different colored dye to increase visualization
organism.
 Before staining the smears are fixed
 Protects the internal structure of cells in fixed position
 Done by two method
 Heat
 Methanol fixation 83
Type of staining methods

1. Simple staining method
2. Differential staining method
3. Special staining method
1. Simple staining method

It is a type of staining method in which only a single dye
is used.
There are two kinds of simple staining methods

A. Positive staining
B. Negative staining
A. Positive staining: The bacteria or its parts are stained
by the dye.
 e.g. Methylene blue stain, Crystal violent stain
B. Negative staining-
The dye stains the background and the bacteria
component remain unstained. e.g. Indian ink stain.
2. Differential staining method

A method in which multiple stains (dye) are used to
distinguish different group of bacteria.
e.g. Gram’s stain, Ziehl-Neelson stain.
Gram’s stain

Principle
The principle of Gram’s stain is that cells are first fixed to
slide by heat or alcohol and stained with a basic dye
 (e.g. crystal violate), which is taken up in similar
amounts by all bacteria.
The slides are then treated with an Gram’s iodine
(iodine KI mixture) to fix (mordant) the crystal violet stain
on Gram positive bacteria, decolorized with acetone or
alcohol, and finally counter stained with Safranin.
 Gram positive bacteria: - stain dark purple with crystal
violet and are not decolorized by acetone or ethanol.
 N.B. The reason for the retention crystal violet by the
gram positive bacteria after decolorization is due to the
presence of more acidic protoplasm (PG layer) of these
organisms which bind to the crystal violate
 Gram negative bacteria: - stain red because after
being stained with crystal violet they are decolorized by
acetone or ethanol and take up red counter stain.
(Neutral red, Safranin or dilute carbol fuchsin).
Procedure of Gram staining

1. Add Gentian violet or crystal violet then wait for 1 min,
wash with water.
2. Add mordant (iodine), then wait for 1 min, wash with
water.
3. Add decolorizer (acetone/ethyl alcohol), then wait for
30s wash with water.
4. Add counter stain safranin/neutral red, then wait for 1
min, wash with water.
5. Air dry and examine under oil immersion microscope.
 Notes: In Gram staining gram positive bacteria appear
purple while gram negative bacteria appear red/pink.
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 Ziehl-Neelson (Acid fast Bacilli-AFB) staining
method

Ziehl-Neelson stain is used for staining mycobacteria
which are hardly stained by Gram‘s staining method.
Once the Mycobacteria is stained with primary stain it
can not be decolorized with acid, so named as acid-fast
bacteria.
The most striking chemical feature of mycobacteria is
their extra ordinary high lipid content in the cell wall
 Making it relative impermeability to stains, acid fastness, unusual
resistance to killing by acid and alkali.
The cell wall of Mycobacteria also contains a peptido-
glycan layer, glycolipids, protein and Mycolic acid
 Principle of Ziehl-Neelson (Acid fast) staining
method

Smear is heat–fixed, flooded with a solution of carbilfusin
(a mixture of basic fuschin and phenol) and heated until
steam rises.
 The heating which facilitate penetration (entrance) of the
primary stain into the bacterium.
After washing with water, the slide is covered with 3%
HCl (decolourizer).
Then washed with water and flooded with methylene blue
( Mycobacterium tuberculosis)
Procedure of Ziehl–Neelsen staining

1. Add carbolfuchsin and heat until vapor is observed
then wait for 5 min, then wash with water.
2. Add decolorizer acid alcohol (3% HCl) wait for 2-3 min
then wash with water.
3. Add counter stain methylene blue/malachite green wait
for 1 min then wash with water.
4. Air dry and examine under oil immersion microscope.
Notes: Mycobacterium tuberculosis appear pink in blue
back ground.

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94
Microbial Examination…

B) Culture:
 identify bacteria at genus and species level
C) Antimicrobial Susceptibility:
 Microorganisms, particularly bacteria, are tested in vitro to
determine whether they are susceptible to antimicrobial agents
D) Serodiagnosis:
 A high or rising titer of specific IgG antibodies or the presence of
specific IgM antibodies may suggest or confirm a diagnosis.
 Bacterial antigen is detected using specific antibodies
E) Molecular techniques (PCR)
 Bacterial nucleic acid is detected
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