Water Activity, Water Glass Dynamics, and the Control of Microbiological Growth in Foods

Water is probably the single most important factor governing microbial spoilage in foods, and the concept of water activity (aw) has been very valuable because measured values generally correlate well with the potential for growth and metabolic activity. Despite some drawbacks (e.g., solute effect),...

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Detalles Bibliográficos
Autor principal: Buera, María del Pilar
Publicado: 1996
Materias:
Microbiological growth
Water activity
Water glass dynamics
glass
water
Argentina
chemistry
food contamination
food control
food handling
food preservation
methodology
quality control
review
standard
thermodynamics
Food Contamination
Food Handling
Food Microbiology
Food Preservation
Glass
Quality Control
Thermodynamics
Water
Acceso en línea:https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_10408398_v36_n5_p465_Chirife
http://hdl.handle.net/20.500.12110/paper_10408398_v36_n5_p465_Chirife
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id paper:paper_10408398_v36_n5_p465_Chirife
record_format dspace
spelling paper:paper_10408398_v36_n5_p465_Chirife2023-06-08T16:00:54Z Water Activity, Water Glass Dynamics, and the Control of Microbiological Growth in Foods Buera, María del Pilar Microbiological growth Water activity Water glass dynamics glass water Argentina chemistry food contamination food control food handling food preservation methodology quality control review standard thermodynamics Argentina Food Contamination Food Handling Food Microbiology Food Preservation Glass Quality Control Thermodynamics Water Water is probably the single most important factor governing microbial spoilage in foods, and the concept of water activity (aw) has been very valuable because measured values generally correlate well with the potential for growth and metabolic activity. Despite some drawbacks (e.g., solute effect), the concept of aw has assisted food scientists in their effort to predict the onset of food spoilage as well as to control food-borne disease hazards in food products. In the last decade the concept of aw has been challenged. It has been suggested that reduced-moisture food products (e.g., low and intermediate) may be nonequilibrium systems and that most of them are in the amorphous metastable state, which is very sensitive to changes in moisture content and temperature. It has been proposed that the glass transition temperature Tg (temperature at which the glass-rubber transition occurs), is a parameter that can determine many product properties, the safety of foods among them. The concept of water dynamics, originating in a food polymer science approach, has been suggested instead of aw to better predict the microbial stability of intermediate-moisture foods. The usage of aw to predict microbial safety of foods has been discouraged on the basis that (1) in intermediate-moisture foods the measured water vapor pressure is not an equilibrium one, and because aw is a thermodynamic concept, it refers only to equilibrium; and (2) the microbial response may differ at a particular aw when the latter is obtained with different solutes. This review analyzes these suggestions on the basis of abundant experimental evidence found in the literature. It is concluded that nonequilibrium effects (e.g., inability of water to diffuse in a semimoist food) appear to be in many cases slow within the time frame (food's shelf life) of the experiments and/or so small that they do not affect seriously the application of the aw concept as a predictor of microbial stability in foods. The claims that a food science polymer approach to understanding the behavior of aqueous sugar glasses and concentrated solutions may be used to predict the microbial stability of food systems is not substantiated by experimental evidence. This approach does not offer, at the present time, a better alternative to the concept of aw as a predictor of microbial growth in foods. It is also recognized that aw has several limitations and should be always used carefully, and this must include precautions regarding the possible influences of nonequilibrium situations. This aspect may be summarized by simply saying that anyone who is going to employ the term water activity must be aware of the implications of its definition. Fil:Del Pilar Buera, M. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. 1996 https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_10408398_v36_n5_p465_Chirife http://hdl.handle.net/20.500.12110/paper_10408398_v36_n5_p465_Chirife
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Microbiological growth
Water activity
Water glass dynamics
glass
water
Argentina
chemistry
food contamination
food control
food handling
food preservation
methodology
quality control
review
standard
thermodynamics
Argentina
Food Contamination
Food Handling
Food Microbiology
Food Preservation
Glass
Quality Control
Thermodynamics
Water
spellingShingle Microbiological growth
Water activity
Water glass dynamics
glass
water
Argentina
chemistry
food contamination
food control
food handling
food preservation
methodology
quality control
review
standard
thermodynamics
Argentina
Food Contamination
Food Handling
Food Microbiology
Food Preservation
Glass
Quality Control
Thermodynamics
Water
Buera, María del Pilar
Water Activity, Water Glass Dynamics, and the Control of Microbiological Growth in Foods
topic_facet Microbiological growth
Water activity
Water glass dynamics
glass
water
Argentina
chemistry
food contamination
food control
food handling
food preservation
methodology
quality control
review
standard
thermodynamics
Argentina
Food Contamination
Food Handling
Food Microbiology
Food Preservation
Glass
Quality Control
Thermodynamics
Water
description Water is probably the single most important factor governing microbial spoilage in foods, and the concept of water activity (aw) has been very valuable because measured values generally correlate well with the potential for growth and metabolic activity. Despite some drawbacks (e.g., solute effect), the concept of aw has assisted food scientists in their effort to predict the onset of food spoilage as well as to control food-borne disease hazards in food products. In the last decade the concept of aw has been challenged. It has been suggested that reduced-moisture food products (e.g., low and intermediate) may be nonequilibrium systems and that most of them are in the amorphous metastable state, which is very sensitive to changes in moisture content and temperature. It has been proposed that the glass transition temperature Tg (temperature at which the glass-rubber transition occurs), is a parameter that can determine many product properties, the safety of foods among them. The concept of water dynamics, originating in a food polymer science approach, has been suggested instead of aw to better predict the microbial stability of intermediate-moisture foods. The usage of aw to predict microbial safety of foods has been discouraged on the basis that (1) in intermediate-moisture foods the measured water vapor pressure is not an equilibrium one, and because aw is a thermodynamic concept, it refers only to equilibrium; and (2) the microbial response may differ at a particular aw when the latter is obtained with different solutes. This review analyzes these suggestions on the basis of abundant experimental evidence found in the literature. It is concluded that nonequilibrium effects (e.g., inability of water to diffuse in a semimoist food) appear to be in many cases slow within the time frame (food's shelf life) of the experiments and/or so small that they do not affect seriously the application of the aw concept as a predictor of microbial stability in foods. The claims that a food science polymer approach to understanding the behavior of aqueous sugar glasses and concentrated solutions may be used to predict the microbial stability of food systems is not substantiated by experimental evidence. This approach does not offer, at the present time, a better alternative to the concept of aw as a predictor of microbial growth in foods. It is also recognized that aw has several limitations and should be always used carefully, and this must include precautions regarding the possible influences of nonequilibrium situations. This aspect may be summarized by simply saying that anyone who is going to employ the term water activity must be aware of the implications of its definition.
author Buera, María del Pilar
author_facet Buera, María del Pilar
author_sort Buera, María del Pilar
title Water Activity, Water Glass Dynamics, and the Control of Microbiological Growth in Foods
title_short Water Activity, Water Glass Dynamics, and the Control of Microbiological Growth in Foods
title_full Water Activity, Water Glass Dynamics, and the Control of Microbiological Growth in Foods
title_fullStr Water Activity, Water Glass Dynamics, and the Control of Microbiological Growth in Foods
title_full_unstemmed Water Activity, Water Glass Dynamics, and the Control of Microbiological Growth in Foods
title_sort water activity, water glass dynamics, and the control of microbiological growth in foods
publishDate 1996
url https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_10408398_v36_n5_p465_Chirife
http://hdl.handle.net/20.500.12110/paper_10408398_v36_n5_p465_Chirife
work_keys_str_mv AT bueramariadelpilar wateractivitywaterglassdynamicsandthecontrolofmicrobiologicalgrowthinfoods
_version_ 1768542748926803968

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