Microbiology Lecture Notes - Controlling Microbial Growth PDF

Summary

This document is a collection of PowerPoint lecture slides on controlling microbial growth. It covers topics such as alteration of cell walls and membranes, damage to proteins and nucleic acids, microbial death rates, and different methods for controlling microbial growth. The material discusses the use of different methods like heat, chemicals, and filtration.

Full Transcript

PowerPoint® Lecture
Presentations prepared by
Mindy Miller-Kittrell,
North Carolina State
University

CHAPTER 9
Controlling
Microbial
Growth in the
Environment
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 Table 9.1 Terminology of Microbial Control

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 Figure 9.1 A plot of microbial death rate.

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 Basic Principles of Microbial Control

Action of Antimicrobial Agents
Alteration of cell walls and membranes
Cell wall maintains integrity of cell
Cells burst due to osmotic effects when damaged
Cytoplasmic membrane contains cytoplasm and controls
passage of chemicals into and out of cell
Cellular contents leak out when damaged
Nonenveloped viruses have greater tolerance of harsh
conditions

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 Basic Principles of Microbial Control

Action of Antimicrobial Agents
Damage to proteins and nucleic acids
Protein function depends on 3-D shape
Extreme heat or certain chemicals denature
proteins
Chemicals, radiation, and heat can alter or destroy
nucleic acids
Produce fatal mutants
Halt protein synthesis through action on RNA

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 Basic Principles of Microbial Control

Tell Me Why
Why does milk eventually go “bad” despite being
pasteurized?

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 The Selection of Microbial Control Methods

Ideally, agents for the control of microbes
should be:
Inexpensive
Fast-acting
Stable during storage
Capable of controlling microbial growth while being
harmless to humans, animals, and objects

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 The Selection of Microbial Control Methods

Factors Affecting the Efficacy of
Antimicrobial Methods
Site to be treated
Harsh chemicals and extreme heat cannot be used on
humans, animals, and fragile objects
Method of microbial control based on site of medical
procedure

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 Figure 9.2 Relative susceptibilities of microbes to antimicrobial agents.

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 The Selection of Microbial Control Methods

Factors Affecting the Efficacy of
Antimicrobial Methods
Relative susceptibility of microorganisms
Germicide classification
High-level germicides
Kill all pathogens, including endospores
Intermediate-level germicides
Kill fungal spores, protozoan cysts, viruses, and
pathogenic bacteria
Low-level germicides
Kill vegetative bacteria, fungi, protozoa, and
some viruses

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 The Selection of Microbial Control Methods

Factors Affecting the Efficacy of
Antimicrobial Methods
Environmental conditions
Temperature and pH
Affect microbial death rates
Alter the efficacy of antimicrobial methods
Organic materials
Interfere with the penetration of heat, chemicals,
and some forms of radiation
May inactivate chemical disinfectants

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 Figure 9.3 Effect of temperature on the efficacy of an antimicrobial chemical.

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 The Selection of Microbial Control Methods

Biosafety Levels
Four levels of safety in labs dealing with pathogens
Biosafety Level 1 (BSL-1)
Handling pathogens that do not cause disease in
healthy humans
Biosafety Level 2 (BSL-2)
Handling moderately hazardous agents
Biosafety Level 3 (BSL-3)
Handling microbes in safety cabinets
Biosafety Level 4 (BSL-4)
Handling microbes that cause severe or fatal
disease

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 Figure 9.4 A BSL-4 worker carrying Ebola virus cultures.

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 The Selection of Microbial Control Methods

Tell Me Why
Why are BSL-4 suits pressurized? Why not just
wear tough regular suits?

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 Physical Methods of Microbial Control

Heat-Related Methods
Effects of high temperatures:
Denature proteins
Interfere with integrity of cytoplasmic membrane and
cell wall
Disrupt structure and function of nucleic acids
Thermal death point
Lowest temperature that kills all cells in broth in
10 minutes
Thermal death time
Time to sterilize volume of liquid at set temperature

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 Figure 9.5 Decimal reduction time (D) as a measure of microbial death rate.

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 Physical Methods of Microbial Control

Heat-Related Methods
Moist heat
Used to disinfect, sanitize, sterilize, and pasteurize
Denatures proteins and destroys cytoplasmic
membranes
More effective than dry heat
Methods of microbial control using moist heat:
Boiling
Autoclaving
Pasteurization
Ultra-high-temperature sterilization

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 Physical Methods of Microbial Control

Heat-Related Methods
Moist heat
Boiling
Kills vegetative cells of bacteria and fungi,
protozoan trophozoites, and most viruses
Boiling time is critical
Different elevations require different
boiling times
Endospores, protozoan cysts, and some viruses
can survive boiling

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 Physical Methods of Microbial Control

Heat-Related Methods
Moist heat
Autoclaving
Pressure applied to boiling water prevents steam
from escaping
Boiling temperature increases as pressure
increases
Autoclave conditions: 121°C, 15 psi, 15 minutes

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 Figure 9.6 The relationship between temperature and pressure.

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 Figure 9.7 An autoclave.

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 Physical Methods of Microbial Control

Dr. Bauman’s Microbiology Video Tutor
For more information, listen to Dr. Bauman describe
uses of an autoclave and how an autoclave
functions.

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 Figure 9.8 Sterility indicators.

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 Physical Methods of Microbial Control

Heat-Related Methods
Moist heat
Pasteurization
Used for milk, ice cream, yogurt, and fruit juices
Not sterilization
Heat-tolerant microbes survive
Pasteurization of milk
Batch method
Flash pasteurization
Ultra-high-temperature pasteurization

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 Physical Methods of Microbial Control

Heat-Related Methods
Moist heat
Ultra-high-temperature sterilization
140°C for 1 to 3 seconds, then rapid cooling
Treated liquids can be stored at room
temperature

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 Table 9.2 Moist Heat Treatments of Milk

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 Physical Methods of Microbial Control

Heat-Related Methods
Dry heat
Used for materials that cannot be sterilized with
moist heat
Denatures proteins and oxidizes metabolic and
structural chemicals
Requires higher temperatures for longer time than
moist heat
Incineration is ultimate means of sterilization

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 Physical Methods of Microbial Control

Refrigeration and Freezing
Decrease microbial metabolism, growth, and
reproduction
Chemical reactions are slower at low temperatures
Liquid water not available
Refrigeration halts growth of most pathogens
Some microbes can multiply in refrigerated foods
Slow freezing more effective than quick freezing
Organisms vary in susceptibility to freezing

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 Physical Methods of Microbial Control

Desiccation and Lyophilization
Desiccation (drying) inhibits growth due to removal
of water
Lyophilization (freeze-drying) used for long-term
preservation of microbial cultures
Prevents formation of damaging ice crystals

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 Figure 9.9 The use of desiccation as a means of preserving apricots in
Pakistan.

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 Figure 9.10 Filtration equipment used for microbial control.

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 Table 9.3 Membrane Filters

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 Figure 9.11 The roles of high-efficiency particulate air (HEPA) filters in
biological safety cabinets.

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 Physical Methods of Microbial Control

Osmotic Pressure
High concentrations of salt or sugar in foods to
inhibit growth
Cells in hypertonic solution of salt or sugar lose water
Fungi have greater ability than bacteria to survive
hypertonic environments

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 Physical Methods of Microbial Control

Radiation
Ionizing radiation
Wavelengths shorter than 1 nm
Electron beams, gamma rays, some X rays
Ejects electrons from atoms to create ions
Ions disrupt hydrogen bonding, oxidize double covalent
bonds, and create hydroxyl radicals
Ions denature other molecules (DNA)
Electron beams effective at killing microbes but do not
penetrate well
Gamma rays penetrate well but require hours to kill
microbes
X rays require long time to kill microbes
Not practical for microbial control
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 Figure 9.12 A demonstration of the increased shelf life of food achieved by
ionizing radiation.

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 Physical Methods of Microbial Control

Radiation
Nonionizing radiation
Wavelengths greater than 1 nm
Excites electrons, causing them to make new
covalent bonds
Affects 3-D structure of proteins and nucleic acids
UV light causes pyrimidine dimers in DNA
UV light does not penetrate well
Suitable for disinfecting air, transparent fluids, and
surfaces of objects

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 Table 9.4 Physical Methods of Microbial Control

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 Physical Methods of Microbial Control

Tell Me Why
Why are Bacillus endospores used as sterility
indicators?

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 Chemical Methods of Microbial Control

Affect microbes’ cell walls, cytoplasmic
membranes, proteins, or DNA
Effect varies with differing environmental
conditions
Often more effective against enveloped viruses
and vegetative cells of bacteria, fungi, and
protozoa

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 Chemical Methods of Microbial Control

Phenol and Phenolics
Denature proteins and disrupt cell membranes
Effective in presence of organic matter
Remain active for prolonged time
Commonly used in health care settings, labs,
and homes
Have disagreeable odor and possible side effects

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 Figure 9.13 Phenol and phenolics.

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 Chemical Methods of Microbial Control

Alcohols
Intermediate-level disinfectants
Denature proteins and disrupt cytoplasmic
membranes
More effective than soap in removing bacteria
from hands
Swabbing of skin with alcohol prior to injection
removes most microbes

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 Chemical Methods of Microbial Control

Halogens
Intermediate-level antimicrobial chemicals
Damage enzymes by denaturation
Widely used in numerous applications
Iodine tablets, iodophors, chlorine treatment, bleach,
chloramines, and bromine disinfection

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 Figure 9.14 Degerming in preparation for surgery on a hand.

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 Chemical Methods of Microbial Control

Oxidizing Agents
Peroxides, ozone, and peracetic acid
Kill by oxidation of microbial enzymes
High-level disinfectants and antiseptics
Hydrogen peroxide can disinfect and sterilize
surfaces
Not useful for treating open wounds due to catalase
activity
Ozone treatment of drinking water
Peracetic acid is an effective sporicide used to
sterilize equipment

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 Chemical Methods of Microbial Control

Surfactants
“Surface active” chemicals
Reduce surface tension of solvents
Soaps and detergents
Soaps have hydrophilic and hydrophobic ends
Good degerming agents but not antimicrobial
Detergents are positively charged organic surfactants
Quatenary ammonium compounds (quats)
Low-level disinfectants
Disrupt cellular membranes
Ideal for many medical and industrial applications

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 Figure 9.15 Quaternary ammonium compounds (quats).

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 Chemical Methods of Microbial Control

Heavy Metals
Heavy-metal ions denature proteins
Low-level bacteriostatic and fungistatic agents
1% silver nitrate to prevent blindness caused by
Neisseria gonorrhoeae
Thimerosal used to preserve vaccines
Copper controls algal growth

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 Figure 9.16 The effect of heavy-metal ions on bacterial growth.

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 Chemical Methods of Microbial Control

Aldehydes
Compounds containing terminal —CHO groups
Cross-link functional groups to denature proteins and
inactivate nucleic acids
Glutaraldehyde disinfects and sterilizes
Formalin used in embalming and disinfection of
rooms and instruments

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 Chemical Methods of Microbial Control

Gaseous Agents
Microbicidal and sporicidal gases used in closed
chambers to sterilize items
Denature proteins and DNA by cross-linking
functional groups
Used in hospitals and dental offices
Disadvantages:
Can be hazardous to people
Often highly explosive
Extremely poisonous
Potentially carcinogenic

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 Chemical Methods of Microbial Control

Enzymes
Antimicrobial enzymes act against microorganisms
Human tears contain lysozyme
Digests peptidoglycan cell wall of bacteria
Use enzymes to control microbes in the environment
Lysozyme used to reduce the number of bacteria
in cheese
Prionzyme can remove prions on medical instruments

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 Chemical Methods of Microbial Control

Antimicrobial Drugs
Antibiotics, semisynthetic, and synthetic chemicals
Typically used for treatment of disease
Some used for antimicrobial control outside the body

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 Table 9.5 Chemical Methods of Microbial Control

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 Chemical Methods of Microbial Control

Methods for Evaluating Disinfectants and
Antiseptics
Phenol coefficient
Evaluates efficacy of disinfectants and antiseptics
Compares an agent’s ability to control microbes to phenol
Greater than 1.0 indicates agent is more effective than
phenol
Has been replaced by newer methods

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 Chemical Methods of Microbial Control

Methods for Evaluating Disinfectants and
Antiseptics
Use-dilution test
Metal cylinders dipped into broth cultures of bacteria
Contaminated cylinder immersed into dilution of
disinfectant
Cylinders removed, washed, and placed into tube of
medium
Most effective agents entirely prevent growth at highest
dilution
Current standard test in the United States
New standard procedure being developed

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 Chemical Methods of Microbial Control

Methods for Evaluating Disinfectants and
Antiseptics
Kelsey-Sykes capacity test
Alternative assessment approved by the European Union
Bacterial suspensions added to the chemical being tested
Samples removed at predetermined times and incubated
Lack of bacterial reproduction reveals minimum time
required for the disinfectant to be effective

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 Chemical Methods of Microbial Control

Methods for Evaluating Disinfectants and
Antiseptics
In-use test
Swabs taken from objects before and after application of
disinfectant or antiseptic
Swabs inoculated into growth medium and incubated
Medium monitored for growth
Accurate determination of proper strength and application
procedure for each specific situation

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 Chemical Methods of Microbial Control

Development of Resistant Microbes
Little evidence that products containing antiseptic and
disinfecting chemicals add to human or animal health
Use of such products promotes development of
resistant microbes

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 Chemical Methods of Microbial Control

Tell Me Why
Many chemical disinfectants and antiseptics act by
denaturing proteins. Why does denaturation kill cells?

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