Abstract
Temperature is an important parameter in bioprocesses, influencing the structure and functionality of almost every biomolecule, as well as affecting metabolic reaction rates. In industrial biotechnology, the temperature is usually tightly controlled at an optimum value. Smart variation of the temperature to optimize the performance of a bioprocess brings about multiple complex and interconnected metabolic changes and is so far only rarely applied. Mathematical descriptions and models facilitate a reduction in complexity, as well as an understanding, of these interconnections. Starting in the 19th century with the “primal” temperature model of Svante Arrhenius, a variety of models have evolved over time to describe growth and enzymatic reaction rates as functions of temperature. Data-driven empirical approaches, as well as complex mechanistic models based on thermodynamic knowledge of biomolecular behavior at different temperatures, have been developed. Even though underlying biological mechanisms and mathematical models have been well-described, temperature as a control variable is only scarcely applied in bioprocess engineering, and as a conclusion, an exploitation strategy merging both in context has not yet been established. In this review, the most important models for physiological, biochemical, and physical properties governed by temperature are presented and discussed, along with application perspectives. As such, this review provides a toolset for future exploitation perspectives of temperature in bioprocess engineering.
Highlights
Predetermined by the applied system, bioprocesses are generally very sensitive to most changes in environmental conditions
Even though underlying biological mechanisms and mathematical models have been well-described, temperature as a control variable is only scarcely applied in bioprocess engineering, and as a conclusion, an exploitation strategy merging both in context has not yet been established
Exploiting existing control variables to their full extent is a reasonable strategy for broadening existing toolsets of monitoring and control
Summary
Predetermined by the applied system, bioprocesses are generally very sensitive to most changes in environmental conditions. Deterministic process models can be used to describe a biological process as a function of a physical condition, like the temperature They may be used in the food sector to estimate product shelf life, determining critical control points of a process, or to maximize productivities and ensure safe distribution chains [8]. Even though knowledge on microbial temperature responses and adaptation, along with descriptions developed by mathematical means, is available, its potential for applied industrial bioprocesses has not been sufficiently exploited. This review provides an overview on available thermo-models with the potential to develop model-assisted or model-derived process control strategies using temperature as a crucial parameter
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