M_T_Ch7_Control of Microbial Growth_s.ppt PDF

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This document is a presentation on the control of microbial growth. It covers definitions, different methods for microbial control, and the effectiveness of each method according to different microbes. It also discusses the different uses of heat, chemical agents, radiation, and other methods.

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Chapter 7 The Control of Microbial Growth SLOs  Define sterilization, disinfection, antisepsis, sanitization, biocide, germicide, bacteriostasis, and asepsis.  Describe the microbial death curve.  Describe the effects of microbial control agents on cellular structures.  Compare effecti...

Chapter 7 The Control of Microbial Growth SLOs  Define sterilization, disinfection, antisepsis, sanitization, biocide, germicide, bacteriostasis, and asepsis.  Describe the microbial death curve.  Describe the effects of microbial control agents on cellular structures.  Compare effectiveness of moist heat (autoclaving, pasteurization) vs.dry heat.  Describe how filtration, low temperature, high pressure, desiccation, and osmotic pressure suppress microbial growth.  Explain how radiation kills cells.  List the factors related to effective disinfection.  Interpret results of use-dilution tests and the disk-diffusion method.  Identify some methods of action and preferred uses of chemical disinfectant  Differentiate between halogens used as antiseptics and as disinfectants.  Identify the appropriate uses for surface-active agents.  List the advantages of glutaraldehyde over other chemical disinfectants.  Identify the method of sterilizing plastic labware.  Explain how microbial control is affected by the type of microbe. Copyright © 2010 Pearson Education, Inc. Terminology  Sepsis: microbial contamination.  Asepsis: absence of significant contamination.  Aseptic surgery techniques prevent microbial contamination of wounds.  Antimicrobial chemicals, expected to destroy pathogens but not to achieve sterilization  Disinfectant: used on objects  Antiseptic: used on living tissue  Nosocomial Copyright © 2010 Pearson Education, Inc.... More Terminology  Sterilization: Removal of all microbial life (heat, filtration)  For food: Commercial sterilization to kill C. botulinum endospores  Sanitization: reduces microbial numbers to safe levels (e.g.: eating utensils)  Bacteriostatic: Inhibits bacterial reproduction  Bactericidal: Kills bacteria  Fungicide, sporicide, germicide, biocide Copyright © 2010 Pearson Education, Inc. Rate of Microbial Death Bacterial populations subjected to heat or antimicrobial chemicals die at a constant rate. Microbial Death Curve, plotted logarithmically, shows this constant death rate as a straight Rate: 90% / min line. Figure 7.1a Copyright © 2010 Pearson Education, Inc. Fig 7.1  How is it possible that a solution containing a million bacteria would take longer to sterilize than one containing a half-million bacteria? 7-2 Copyright © 2010 Pearson Education, Inc. Effectiveness of Antimicrobial Treatment Depends on  Time it takes to kill a microbial population is proportional to number of microbes.  Microbial species and life cycle phases (e.g.: endospores) have different susceptibilities to physical and chemical controls.  Organic matter may interfere with heat treatments and chemical control agents.  Exposure time: Longer exposure to lower heat produces same effect as shorter time at higher heat. Copyright © 2010 Pearson Education, Inc. Actions of Microbial Control Agents  Alternation of membrane permeability  Damage to proteins  Damage to nucleic acids Copyright © 2010 Pearson Education, Inc. Physical Methods of Microbial Control  Heat is very effective (fast and cheap).  Thermal death point (TDP): Lowest temperature at which all cells in a culture are killed in 10 min.  Thermal death time (TDT): Time to kill all cells in a culture  Decimal Reduction Time (DRT): Minutes to kill 90% of a population at a given temperature Table 7.2 Copyright © 2010 Pearson Education, Inc. Moist Heat Sterilization  Denatures proteins  Autoclave: Steam under pressure  Most dependable sterilization method  Steam must directly contact material to be sterilized.  Pressurized steam reaches higher temperatures.  Normal autoclave conditions: 121.5C for 15 min.  Prion destruction: 132C for 4.5 hours  Limitations of the autoclave Copyright © 2010 Pearson Education, Inc. Pasteurization  Significant number reduction (esp. spoilage and pathogenic organisms) does not sterilize!  Historical goal: destruction of M. tuberculosis  Classic holding method: 63C for 30 min  Flash pasteurization (HTST): 72C for 15 sec. Most common in US. Thermoduric organisms survive  Ultra High Temperature (UHT): 140C for < 1 sec. Technically not pasteurization because it sterilizes. Copyright © 2010 Pearson Education, Inc. Dry heat sterilization kills by oxidation  Flaming of loop  Incineration of carcasses  Anthrax  Foot and mouth disease  Bird flu  Hot-air sterilization Hot-air Autoclave Equivalent 121˚C, 15 170˚C, 2 hr treatments min Copyright © 2010 Pearson Education, Inc. Filtration  Air filtration using high efficiency particulate air (HEPA) filters. Effective to 0.3 m  Membrane filters for fluids.  Pore size for bacteria: 0.2 – 0.4 m  Pore size for viruses: 0.01 m Fig 7.4 Copyright © 2010 Pearson Education, Inc. Low Temperature  Slows enzymatic reactions  inhibits microbial growth  Freezing forms ice crystals that damage microbial cells  Refrigeration (watch out for _________________!, deep freezing, lyophilization Various Other Methods  High pressure in liquids denatures bacterial proteins and preserves flavor  Desiccation prevents metabolism  Osmotic pressure causes plasmolysis Copyright © 2010 Pearson Education, Inc. Ionizing Radiation  X-rays, -rays, electron beams dislodge e- from atoms production of free radicals and other highly reactive molecules  Commonly used Cobalt-60 radioisotope  Salmonella and Pseudomonas are particularly sensitive  Sterilization of heat sensitive materials: drugs, vitamins, herbs, suture material  Also used as “cold pasteurization” of food  Consumer fears!? Copyright © 2010 Pearson Education, Inc. Nonionizing Radiation: UV light  Most effective wave legnth ~ 260 nm  Effect: thymine dimers  Actively dividing organisms are more sensitive because thymine dimers cause....?  Used to limit air and surface contamination. Use at close range to directly exposed microorganisms  E.g.: germicidal lamps in OR, cafeteria, and our lab ?? Copyright © 2010 Pearson Education, Inc. Nonionizing Radiation: Microwave  Wavelength: 1 mm – 1m  H2O quickly absorbs energy release as heat to environment  Indirect killing of bacteria through heat  Solid food heats unevenly, why? Fig 7.5 Copyright © 2010 Pearson Education, Inc. Chemical Methods of Microbial Control  Few chemical agents achieve sterility.  Consider presence of organic matter, degree of contact with microorganisms, and temperature  Disinfectants regulated by EPA Antiseptics regulated by FDA  Use-dilution test 1. Metal rings dipped in test bacteria are dried. 2. Dried cultures of S. choleraesuis, S. aureus, and P. aeruginosa are placed in disinfectant for 10 min at 20C. 3. Rings are transferred to culture media to determine whether bacteria survived treatment. Copyright © 2010 Pearson Education, Inc. Disk-diffusion Method Disk of filter paper is soaked with a chemical and placed on an inoculated agar plate; a zone of inhibition indicates effectiveness. Fig 7.6 Copyright © 2010 Pearson Education, Inc. Types of Disinfectants  Phenol = carbolic acid (historic importance)  Phenolics: Cresols (Lysol) - disinfectant  Bisphenols  Hexachlorophene (pHisoHex, prescription), hospitals, surgeries, Fig 7.7 nurseries  Triclosan (toothpaste, antibacerial soaps, etc.) Phenol and derivatives disrupt plasma membranes (lipids!) and lipid rich cell walls (??) Remain active in presence of organic compoundsP Copyright © 2010 Pearson Education, Inc. Halogens Chlorine  Oxidizing agent  Widely used as disinfectant  Forms bleach (hypochlorous acid) when added to water.  Broad spectrum, not sporicidal (pools, drinking water) Iodine More reactive, more germicidal. Alters protein synthesis and membranes. Tincture of iodine (solution with alcohol) wound antiseptic Iodophors combined with an organic molecule iodine detergent complex (e.g. Betadine®). Occasional skin sensitivity, partially inactivated by organic debris, poor sporicidal activity. Copyright © 2010 Pearson Education, Inc. Alcohols  Ethyl (60 – 80% solutions) and isopropyl alcohol  Denature proteins, dissolve lipids  No activity against spores and poorly effective against viruses and fungi  Easily inactivated by organic debris  Also used in hand sanitizers and cosmetics Copyright © 2010 Pearson Education, Inc. Table 7.6 Heavy Metals Oligodynamic action: toxic effect due to metal ions combining with sulfhydryl (—SH) and other groups  proteins are denatured.  Mercury (HgCl2, Greeks & Romans for skin lesions); Thimerosal  Copper against chlorophyll containing organisms Algicides  Silver (AgNO3): Antiseptic for eyes of newborns  Zinc (ZnCl2) in mouthwashes, ZnO in antifungal in paint Copyright © 2010 Pearson Education, Inc. Surface Acting Ingredients / Surfactants  Soaps and Detergents  Major purpose of soap: Mechanical removal and use as wetting agent  Definition of detergents  Acidic-Anionic detergents Anion reacts with plasma membrane. Nontoxic, non-corrosive, and fast acting. Laundry soap, dairy industry.  Cationic detergents Quarternary ammonium compounds (Quats). Strongly bactericidal against against wide range, but esp. Gram+ bacteria Soap Degerming Acid-anionic detergents Sanitizing Quarternary ammonium Strongly bactericidal, compounds denature proteins, disrupt (cationic detergents) Copyright © 2010 Pearson Education, Inc. plasma membrane Chemical Food Preservatives Sulfur dioxide wine Organic acids Inhibit metabolism Sorbic acid, benzoic acid, and calcium propionate Control molds and bacteria in foods and cosmetics Sodium nitrate and nitrite prevents endospore germination. In meats. Conversion to nitrosamine (carcinogenic) Copyright © 2010 Pearson Education, Inc. Aldehydes and Chemical Sterilants Aldehydes (alkylating agents)  Inactivate proteins by cross-linking with functional groups (–NH2, –OH, –COOH, –SH)  Glutaraldehyde: Sterilant for delicate surgical instruments (Kills S. aureus in 5, M. tuberculosis in 10 min)  Formaldehyde: Virus inactivation for vaccines Chemical Sterilants for heat sensive material  Denature proteins  Ethylene oxide Copyright © 2010 Pearson Education, Inc. Plasma  Luminous gas with free radicals that destroy microbes  Use: Tubular instruments, hands, etc. Copyright © 2010 Pearson Education, Inc. Hydrogen Peroxide: Oxidizing agent Inactivated by catalase  Not good for open wounds Good for inanimate objects; packaging for food industry (containers etc.) 3% solution (higher conc. available) Esp. effective against anaerobic bacteria (e.g.: Effervescent action, may be useful for wound cleansing through removal of tissue debris Copyright © 2010 Pearson Education, Inc. Microbial Characteristics and Microbial Control Fig 7.11 Copyright © 2010 Pearson Education, Inc.

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