On the use of the gompertz model to predict microbial thermal inactivation under isothermal and non-isothermal conditions

Maria M. Gil, Fátima A. Miller, Teresa R.S. Brandão, Cristina L.M. Silva*

*Corresponding author for this work

Research output: Contribution to journalReview articlepeer-review

59 Citations (Scopus)
16 Downloads

Abstract

Food processes should be designed to provide an adequate margin of safety against microbiological risk of food poisoning and food spoilage throughout shelf life. In this field, the use of mathematical models that describe the microorganisms' kinetics in such conditions is an important tool for convenient design, control and optimization of efficient processes. If those models are accurate and precise, one can extract the best aiming at predictive purposes. The Gompertz equation is commonly applied to describe sigmoidal kinetics. Besides the proven adequacy of the model in those kinetics descriptions, most of the reported works do not use Gompertz equation in the most convenient form, and insightful information could be obtained with re-parameterized forms. This work aims at reviewing the use of the Gompertz model to describe inactivation, as well as re-parameterized forms that include parameters related to the survival curve features. Microbial survival often presents a shoulder prior to inactivation, followed by a linear phase (corresponding to a maximum inactivation rate) and a tail residual population. The versatility of the Gompertz model in describing kinetics with different shapes, varying from a log-linear tendency till a complete sigmoidal shape, makes it attractive for predictive purposes, both under static and dynamic temperature conditions. Drawbacks and critical features of the model, when it is applied to microbial responses, will be overview.

Original languageEnglish
Pages (from-to)17-25
Number of pages9
JournalFood Engineering Reviews
Volume3
Issue number1
DOIs
Publication statusPublished - 1 Mar 2011

Keywords

  • Gompertz model
  • Inactivation kinetics
  • Isothermal and non-isothermal conditions

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