Culture media & methods

CULTURE MEDIA
&
CULTURE METHODS

- Kalpesh Anil Zunjarrao

Need for Culture media:
• Bacteria: mixed population in nature
• By appropriate procedures they have to be grown
separately (isolated) on culture media and obtained as
pure culture for study
• Medium → Nutrients → support growth

Culture medium

Liquid medium

Solid medium

Liquid medium:
•
•
•
•

Diffused growth
No characteristics for identification
Difficult to isolate
Earliest liquid medium: urine or meat broth used by Louis
Pasteur

Solid medium:
• Distinct colony morphology
• Characteristics → easy to identify
• Colony – macroscopically visible collection of millions of
bacteria originating from a single bacterial cell

• Earliest solid medium:
Cooked cut potato by Robert Koch
• Gelatin - not satisfactory
- liquefy at 24oC
Agar
• Frau Hesse
• Universally used for preparing solid medium
• Obtained from seaweed: Gelidium
• No nutritive value
• Not affected by the growth of the bacteria.
• Melts at 98°C & sets at 42°C
• 2% agar is employed in solid medium

Types of culture media
I.

II.

Based on their consistency
a) Solid medium
b) Liquid medium
c) Semi solid medium
Based on the constituents/ ingredients
a) Simple medium
b) Complex medium
c) Synthetic or defined medium
d) Special media

Special media
–
–
–
–
–
–
–
–

Enriched media
Enrichment media
Selective media
Indicator media
Differential media
Sugar media
Transport media
Media for biochemical reactions

III.Based on Oxygen requirement
- Aerobic media
- Anaerobic media

Solid media – contains 2% agar
• Colony morphology, pigmentation, hemolysis can be
appreciated.
• Eg: Nutrient agar, Blood agar
Liquid media – no agar.
• For inoculum preparation, Blood culture, continuous
culture.
• Eg: Nutrient broth

Semi solid medium – 0.5% agar.
• Eg: Motility medium

Solid medium

Liquid
medium

Semi-solid medium

Simple media / basal media:
• Most common in routine diagnostic laboratories
Eg: Nutrient Broth, Nutrient Agar
• NB consists of peptone, meat extract, NaCl, water
• NB + 0.5% Glucose = Glucose Broth
• NB + 2% agar = Nutrient agar
• Agar conc. Reduced (0.2 - 0.5%) = Semi-solid medium

Complex media
• Media other than basal media.
• They have added complex ingredients such as yeast
extract or casein hydrolysate, which consist of a mixture
of many chemical species in unknown proportions
• Provide special nutrients

Synthetic or defined media
•
•
•
•

Media prepared from pure chemical substances
exact composition is known
Used for special studies, eg. metabolic requirements
Eg: peptone water- (1% peptone + 0.5% NaCl in water)

Enriched media
• Substances like blood, serum, egg are added to the basal
medium.
• Used to grow bacteria that are exacting in their nutritional
needs.
• Eg: Blood agar, Chocolate agar
Blood
agar

Chocolate
agar

Enrichment media
• Liquid media used to isolate pathogens from a mixed
culture.
• Stimulate growth of desired bacterium
Inhibit growth of unwanted bacterium
• Media is incorporated with inhibitory substances to
suppress the unwanted organism → increase in numbers of
desired bacteria
• Eg:
Selenite F Broth – for the isolation of Salmonella, Shigella
Tetrathionate Broth – inhibit coliforms
Alkaline Peptone Water – for Vibrio cholerae

Selenite F Broth

Tetrathionate
Broth

Alkaline Peptone
water

Selective media
• The inhibitory substance is added to a solid media
• Increase in number of colonies of desired bacterium
Eg:
• Desoxycholate citrate medium for dysentery bacilli
• Mac Conkey’s medium for gram negative bacteria
• TCBS – for V. cholerae
• LJ medium – M. tuberculosis

Mac Conkey’s medium

Thiosulfate citrate
bile salts sucrose (TCBS)
agar

Deoxycholate citrate agar

LJ media

Indicator media
• contain an indicator which changes its colour when a
bacterium grows in them
• Eg:
Wilson-Blair medium – S. typhi forms black colonies
McLeod’s medium (Potassium tellurite)– Diphtheria
bacilli

Wilson-Blair Medium

McLeod’s medium

Urease producing bacteria

Urease

Urea → CO2 + NH3

NH3 → Medium turns pink

Urease medium

Blood agar:
shows three types of Hemolysis
α Hemolysis
β Hemolysis
γ Hemolysis

Differential media
• Substances incorporated in it enabling it to distinguish
between bacteria.
• Eg: Mac Conkey’s medium
– Peptone
– Lactose
– Agar
– Neutral red
– Taurocholate
• Distinguish between lactose fermenters & non lactose
fermenters.

MacConkey agar:
• Lactose fermenters – Pink colonies
• Non lactose fermenters – colourless colonies

Sugar media
• Media containing any fermentable substance
• Eg: glucose, arabinose, lactose, starch etc.
• Media consists:
1% of the sugar in peptone water + Indicator
• Contain a small tube (Durham’s tube) for the detection of
gas by the bacteria

Transport media
• Media used for transporting the samples.
• Delicate organisms may not survive the time taken for
transporting the specimen without a transport media.
• Eg:
– Stuart’s medium – non nutrient soft agar gel containing
a reducing agent & charcoal
used for Gonnococci
– Buffered glycerol saline – enteric bacilli

Anaerobic media
• These media are used to grow anaerobic organisms.
• Eg: Robertson’s cooked meat medium, Thioglycolate
medium.

CULTURE METHODS
• Culture methods employed depend on the purpose for
which they are intended.
• Purposes:
– To isolate bacteria in pure cultures.
– To demonstrate their properties.
– To obtain sufficient growth for the preparation of
antigens and for other tests.
– For bacteriophage & bacteriocin susceptibility.
– To determine sensitivity to antibiotics.
– To estimate viable counts.
– Maintain stock cultures.

Culture methods include:
• Streak culture
• Lawn culture
• Stroke culture
• Stab culture
• Pour plate method
• Liquid culture
• Anaerobic culture methods

STREAK CULTURE
• Used for the isolation of bacteria in pure culture from
clinical specimens.
• Platinum wire or Nichrome wire is used.
• One loopful of the specimen is transferred onto the
surface of a well dried plate.
• Spread over a small area at the periphery.
• The inoculum is then distributed thinly over the plate by
streaking it with a loop in a series of parallel lines in
different segments of the plate.
• On incubation, separated colonies are obtained over the
last series of streaks.

LAWN CULTURE
• Provides a uniform surface growth of the bacterium.
• Uses
– For bacteriophage typing.
– Antibiotic sensitivity testing.
– In the preparation of bacterial antigens and vaccines.
• Lawn cultures are prepared by flooding the surface of the
plate with a liquid suspension of the bacterium.

Antibiotic sensitivity testing

STROKE CULTURE
• Stroke culture is made in tubes containing
agar slope / slant.

• Uses
– Provide a pure growth of bacterium for
slide agglutination and other diagnostic
tests.

STAB CULTURE
• Prepared by puncturing a suitable medium – gelatin or
glucose agar with a long, straight, charged wire.
• Uses
– Demonstration of gelatin liquefaction.
– Oxygen requirements of the bacterium under study.
– Maintenance of stock cultures.

POUR PLATE CULTURE
• Agar medium is melted (15 ml) and cooled to 45oC.
• 1 ml of the inoculum is added to the molten agar.
• Mix well and pour to a sterile petri dish.
• Allow it to set.
• Incubate at 37oC, colonies will be distributed throughout
the depth of the medium.
• Uses
– Gives an estimate of the viable bacterial count in a suspension.
– For the quantitative urine cultures.

LIQUID CULTURES
• Liquid cultures are inoculated by touching with a
charged loop or by adding the inoculum with pipettes or
syringes.
• Uses
– Blood culture
– Sterility tests
– Continuous culture methods
• Disadvantage
– It does not provide a pure culture from mixed inocula.

ANAEROBIC CULTURE METHODS
• Anaerobic bacteria differ in their requirement and
sensitivity to oxygen.
• Cl. tetani is a strict anaerobe - grows at an oxygen tension
< 2 mm Hg.

Methods:
–
–
–
–
–

Production of vacuum
Displacement of oxygen with other gases
Chemical method
Biological method
Reduction of medium

Production of vacuum:
• Incubate the cultures in a vacuum desiccators.
Displacement of oxygen with other gases
• Displacement of oxygen with hydrogen, nitrogen,
helium or CO2.
• Eg: Candle jar

Chemical method
• Alkaline pyrogallol absorbs oxygen.
• Chromium and Sulphuric acid

McIntosh – Fildes’ anaerobic jar
• Consists of a metal jar or glass jar with a metal lid which
can be clamped air tight.
• The lid has 2 tubes – gas inlet and gas outlet
• The lid has two terminals – connected to electrical supply.
• Under the lid – small grooved porcelain spool, wrapped
with a layer of palladinised asbestos.

Working:
• Inoculated plates are placed inside the jar and the lid
clamped air tight.
• The outlet tube is connected to a vacuum pump and the air
inside is evacuated.
• The outlet tap is then closed and the inlet tube is
connected to a hydrogen supply.
• After the jar is filled with hydrogen, the electric terminals
are connected to a current supply, so that the palladinised
asbestos is heated.
• Act as a catalyst for the combination of hydrogen with
residual oxygen.

Gaspak
• Commercially available disposable envelope.
• Contains chemicals which generate H2 and CO2
on addition of water.
• Cold catalyst – permits combination of
Hydrogen & Oxygen
• Indicator is used – reduced methylene blue.
– Colourless – anaerobically
– Blue colour – on exposure to oxygen

Biological method
• Absorption of oxygen by incubation with aerobic
bacteria, germinating seeds or chopped vegetables.
Reduction of oxygen
• By using reducing agents – 1% glucose, 0.1%
Thioglycolate

Bibliography:
Ananthnarayan and Paniker’s Textbook of Microbiology

Culture media & methods

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