Vinicio Serment‐Moreno scite author profile

A recently proposed Gompertz model (GMPZ) approach describing microbial inactivation kinetics by high-pressure processing (HPP) incorporated the initial microbial load (N ) and lower microbial quantification limit (N ), and simplified the dynamic effects of come-up time (CUT). The inactivation of Listeria innocua in milk by HPP treatments at 300, 400, 500, and 600 MPa and pressure holding times (t ) ≤10 min was determined experimentally to validate this model approach. Models based on exponential, logistic-exponential, and inverse functions were evaluated to describe the effect of pressure on the lag time (λ) and maximum inactivation rate (μ ), whereas the asymptote difference (A) was fixed as A = log (N /N ). Model performance was statistically evaluated and further validated with additional data obtained at 450 and 550 MPa. All GMPZ models adequately fitted L. innocua data according to the coefficient of determination (R ≥ 0.95) but those including a logistic-exponential function for μ (P) were superior (R ≥ 0.97). These GMPZ versions predicted that approximately 597 MPa is the theoretical pressure level (P ) at which microbial inactivation begins during CUT, mathematically defined as λ (P = P ) = t , and matching the value observed on the microbial survival curve at 600 MPa. As pressure increased, predictions tended to slightly underestimate the HPP lethality in the tail section of the survival curve. This may be overseen in practice since the observed microbial counts were below the predicted log N values. Overall, the modeling approach is promising, justifying further validation work for other microorganisms and food systems.

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Non-thermal Technologies as Alternative Methods for Saccharomyces cerevisiae Inactivation in Liquid Media: a Review

Paniagua-Martínez

Ramirez-Martinez

Serment‐Moreno

et al. 2018

Food Bioprocess Technol

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Vinicio Serment‐Moreno

High-pressure Processing: Kinetic Models for Microbial and Enzyme Inactivation

Evaluation of High Pressure Processing Kinetic Models for Microbial Inactivation Using Standard Statistical Tools and Information Theory Criteria, and the Development of Generic Time-Pressure Functions for Process Design

Microstructural and Physiological Changes in Plant Cell Induced by Pressure: Their Role on the Availability and Pressure-Temperature Stability of Phytochemicals

A Gompertz Model Approach to Microbial Inactivation Kinetics by High‐Pressure Processing (HPP): Model Selection and Experimental Validation

Non-thermal Technologies as Alternative Methods for Saccharomyces cerevisiae Inactivation in Liquid Media: a Review

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