Search for notes by fellow students, in your own course and all over the country.
Browse our notes for titles which look like what you need, you can preview any of the notes via a sample of the contents. After you're happy these are the notes you're after simply pop them into your shopping cart.
Title: Control of microbial growth
Description: 1st year Undergraduate, Biomedical science Physical & chemical antimicrobial agents
Description: 1st year Undergraduate, Biomedical science Physical & chemical antimicrobial agents
Document Preview
Extracts from the notes are below, to see the PDF you'll receive please use the links above
Control of microbial growth
Effected in two basic ways:
-
Killing microorganisms and Inhibiting microbial growth
Involves the use of: Physical/Chemical agents that kill or prevent growth
Principles of microbial control
-
Prevention → Control of growth to prevent infection
-
Sterilization → Complete destruction
- No ‘levels’ of sterilization → All or Nothing
- Utilizes; Heat, Radiation, Some chemicals and Physical removal
Disinfection → reducing growth on non-living surfaces
-
(Organic matter interferes with heat treatments and chemical control agents)
Antisepsis → reducing growth on living tissue
Physical Methods
Heat
Most frequent and widely used
1
...
Time of Application
3
...
Fresh or cooked foods are flash frozen
2
...
Foods are sealed in moisture and oxygen free packaging
4
...
s
...
for 30 min kills everything
Moist Heat, Pasteurization
Denatures proteins
Kills pathogens in food products
Dry Heat, Flaming
Incineration of contaminants
Used for inoculating loop
Dry Heat, Hot air oven
Oxidation & Denatures proteins
170°C for 2 hours; Used for glassware & instrument sterilization
Filtration
Separation of bacteria from liquid
(HEPA: from air)
Used for heat sensitive liquids
Cold, Lyophilization (also
desiccation)
Desiccation and low temperature
Used for food & drug preservation; Does not necessarily kill so
used for Long-term storage of bacterial cultures
Cold, Refrigeration
Decreased chemical reaction rate
Bacteriostatic
Osmotic Pressure,
Addition of salt or sugar
Plasmolysis of contaminants
Used in food preservation (less effective against fungi)
Radiation, UV
DNA damage (thymine dimers)
Limited penetration
Radiation, X-rays
DNA damage
Used for sterilizing medical supplies
Strong vis
...
Less effect on appearance and texture
Controversy
...
Effective against
Aerobic bacteria (not
obligate/facultative anaerobes)
Bind to bacterial 30S ribosomal
subunit (some work by binding
to the 50S subunit)
Lincomycin
Gram-
Aminoglycosides
Streptomycin,
Tobramycin
Gentamicin
Bacterial
type
Antibiotic Class
Example
Microorganisms
Mechanism of action
Gram+/-
Tetracyclines
Tetracycline
Syphilis, chlamydia, Lyme disease, mycoplasmal infections,
rickettsia
Broad spectrum, inhibit protein
synthesis at 30S subunit
Efficient against Gram+
Disrupt the synthesis of the
peptidoglycan layer of bacterial cell
walls
...
The greater the diameter of the zone, the higher the efficacy of the antibiotic
Antibiotic resistance
-
Growing Problem
Indiscriminant and inappropriate use
Super Bugs: Methicillin Resistant S
...
tuberculosis
Title: Control of microbial growth
Description: 1st year Undergraduate, Biomedical science Physical & chemical antimicrobial agents
Description: 1st year Undergraduate, Biomedical science Physical & chemical antimicrobial agents