Microbiology
culture is a method for growing and studying microorganisms under controlled
conditions in a lab. This technique allows scientists to observe microbial
behavior, diagnose infections, and test the effectiveness of antibiotics for developing
new treatments.
- Liquid Media:
Known as Broth and it do not contain agar (the solidifying agent) this
type of media allows bacteria to grow throughout the liquid.
- Solid Media: This contains agar, a gelatinous substance that provides a surface for bacteria to grow, making it easier to isolate and count colonies.
Agar is derived
from the cell walls of red algae, primarily from the genera Gelidium
and Gracilaria. Here’s a detailed look at what agar is and its various
applications.
Agar is a complex polysaccharide composed mainly of two components: agarose and agaropectin.
- Agarose
is responsible for the gel-like properties of agar, forming a three-dimensional
matrix that traps water.
- Agaropectin
contains a mixture of sulfate esters, pyruvic acid, and other molecules that
contribute to agar’s physical characteristics.
Agar is known for its:
- Gelation
Temperature: It solidifies at around 32-40°C (90-104°F) and
melts at approximately 85°C (185°F). This makes it very useful for
microbiological cultures, as it remains solid at human body temperature.
- Transparency:
When solidified, agar forms a clear gel, allowing for easy observation of
microbial colonies.
- Non-reactivity:
Agar is generally inert and does not react with most substances, making it a
reliable medium for various applications.
Production Process
- Harvesting: Red algae are harvested from marine environments.
- Extraction: The algae are boiled to extract agar, which is then filtered to remove impurities.
- Gelation and Drying: The extracted solution is cooled to form a gel, which is then dehydrated and processed into powder, flakes, or bars.
Uses in Microbiology
Culture
Media: Agar is most famously used as a solidifying agent in microbiological
culture media mostly in Agar plates, or Petri dishes and test tubes. It
provides a stable and nutrient-rich environment for microorganisms (bacteria,
fungi) to grow and isolate in the form of colonies
Making
Selective and differential media: Agar can be combined with various nutrients,
dyes, and inhibitors to create media that select for or differentiate between
specific types of microorganisms.
Steps in
Microbiological Culture
Sample
Collection: The process starts with collecting a sample from
a patient, environment, or other sources.
Inoculation: The sample is then introduced into the culture medium by:
- Streak Plate Method: Involves spreading a sample over an agar plate to isolate individual colonies.
- Pour Plate Method: A sample is mixed with molten agar at 50 degrees centigrade and pouring it into a dish to grow colonies throughout the medium.
- Spread Plate Method: Spreading a liquid sample evenly over the surface of an agar plate for uniform growth.
Incubation:
The inoculated medium is kept at specific temperatures to promote microbial
growth.
Observation:
Scientists monitor the growth, noting characteristics like colony shape, size,
and color.
Identification:
Various tests, including biochemical and molecular methods, help identify the
microorganisms.
Types of
Culture Media
Different
types of culture media serve specific purposes based on their composition and
intended use. Here’s a detailed look at various culture media and their
applications.
1. Nutrient
Media
Example:
Nutrient Agar/Broth
Composition:
Contains peptone, beef extract, and agar (for solid media).
Use: General
purpose media used to grow a wide variety of non-fastidious (no special
requirements) microorganisms. It supports the growth of many types of bacteria
and fungi and is commonly used for routine lab work.
2. Selective
Media
Selective
media contain substances that inhibit the growth of certain microorganisms
while allowing others to grow.
Example:
MacConkey Agar
Composition:
Contains bile salts, crystal violet, lactose, and neutral red.
Use: Selects
for Gram-negative bacteria and differentiates lactose fermenters (pink
colonies) from non-fermenters (colorless colonies). Commonly used to isolate
Enterobacteriaceae and related Gram-negative rods from clinical specimens.
3. Differential Media
Differential
media distinguish between different types of microorganisms based on their
biological characteristics.
Example:
Blood Agar
Composition:
Nutrient agar supplemented with 5-10% sheep or horse blood.
Use:
Differentiates bacteria based on their hemolytic properties (alpha, beta, or
gamma hemolysis). Useful for isolating and identifying pathogenic bacteria like
Streptococcus species.
4. Enriched
Media
Enriched
media are fortified with nutrients to support the growth of fastidious
organisms.
Example:
Chocolate Agar
Composition:
Heated blood agar, which releases factors V (NAD) and X (hemin) necessary for
the growth of certain bacteria.
Use:
Supports the growth of fastidious organisms such as Haemophilus species
and Neisseria species, which require additional growth factors not
present in standard nutrient agar.
5. Selective
and Differential Media
Some media
are both selective and differential, providing a dual function.
Example:
Mannitol Salt Agar (MSA)
Composition:
High salt concentration, mannitol, and phenol red.
Use:
Selects for halotolerant bacteria like Staphylococci and differentiates based
on mannitol fermentation. Mannitol fermenters (e.g., Staphylococcus aureus)
produce yellow colonies due to acid production, while non-fermenters (e.g., Staphylococcus
epidermidis) remain pink.
6. Transport
Media
Transport
media are used to preserve specimens and maintain the viability of organisms
during transport to the laboratory.
Example:
Stuart's Transport Medium
Composition:
Contains buffers and reducing agents, lacks nutrients.
Use:
Maintains viability of microorganisms in clinical specimens without allowing
them to multiply, ideal for transporting throat, wound, and urogenital swabs.
7. Anaerobic
Media
Anaerobic
media are designed to support the growth of anaerobes by creating an
oxygen-free environment.
Example:
Thioglycollate Broth
Composition:
Contains thioglycollate and cystine to reduce oxygen levels.
Use:
Cultivates anaerobic bacteria by providing a low-oxygen environment. The broth
gradient allows both aerobic and anaerobic bacteria to grow in different zones.
8. Chromogenic Media
Chromogenic
media contain substrates that produce colored compounds when metabolized by
specific microorganisms.
Example:
CHROMagar
Composition:
Contains chromogenic substrates specific to the enzymes of target organisms.
Use:
Rapid identification and differentiation of various bacteria and yeast species
based on colony color. Commonly used in clinical microbiology to identify
urinary tract pathogens and Candida species.
9. Minimal
Media
Minimal media
contain the minimum nutrients necessary for the growth of wild-type bacteria or
prototrophs.
Example:
M9 Medium
Composition:
Contains glucose, salts, and minimal growth factors.
Use:
Used to culture genetically modified organisms or to study bacterial growth
under nutrient-limiting conditions. Ideal for selecting bacteria with specific
nutritional requirements.
0 Comments