The microbial growth in multi-substrate environments may be viewed as an optimal resources allocation problem. The optimization aims at maximizing some biological objective like the biomass growth. The models developed using this hypothesis are called "cybernetic" and they represent the complex cell structure as an optimizing function that regulates the intracellular enzymatic machinery. In this work, a cybernetic model was developed to represent the growth of two E. coli strains (JM 109 and BL 21 -DE3-) on a medium containing glucose and glycerol as carbon and energy sources. The model was able to accurately simulate the biomass growth, the substrates consumption and the growth-rate profiles
The need for the development of economic high plasmid production in Escherichia coli cultures is eme...
Clustered microbial communities are omnipresent in the food industry, e.g., as colonies of microbial...
The current production of a number of commodity chemicals relies on the exploitation of fossil fuels...
The microbial growth in multi-substrate environments may be viewed as an optimal resources allocatio...
Growth of microorganisms on substitutable substrate mixtures display diverse growth dynamics charact...
A comprehensive optimal model has been developed to simulate microbial growth for simultaneous utili...
A comprehensive moel is developed based on an optimal strategy describing varied microbial growth ph...
Mathematical models for microbial growth based on reaction kinetics are generally successful in pred...
Flux balance analysis in combination with the decomposition of metabolic networks into elementary mo...
Cybernetic modeling has traditionally been used in the modeling of microbial growth on multiple subs...
dx.doi.org/10.1590/0104-6632.20140312s00002587 *To whom correspondence should be addresse
Steady state multiplicity in continuous cell cultures is studied by means of two different types of ...
The cybernetic modeling framework provides an interesting approach to model the regulatory phenomena...
Mathematical models which utilize standard reaction kinetics to describe microbial growth are genera...
Understanding the growth behavior of microorganisms using modeling and optimization techniques is an...
The need for the development of economic high plasmid production in Escherichia coli cultures is eme...
Clustered microbial communities are omnipresent in the food industry, e.g., as colonies of microbial...
The current production of a number of commodity chemicals relies on the exploitation of fossil fuels...
The microbial growth in multi-substrate environments may be viewed as an optimal resources allocatio...
Growth of microorganisms on substitutable substrate mixtures display diverse growth dynamics charact...
A comprehensive optimal model has been developed to simulate microbial growth for simultaneous utili...
A comprehensive moel is developed based on an optimal strategy describing varied microbial growth ph...
Mathematical models for microbial growth based on reaction kinetics are generally successful in pred...
Flux balance analysis in combination with the decomposition of metabolic networks into elementary mo...
Cybernetic modeling has traditionally been used in the modeling of microbial growth on multiple subs...
dx.doi.org/10.1590/0104-6632.20140312s00002587 *To whom correspondence should be addresse
Steady state multiplicity in continuous cell cultures is studied by means of two different types of ...
The cybernetic modeling framework provides an interesting approach to model the regulatory phenomena...
Mathematical models which utilize standard reaction kinetics to describe microbial growth are genera...
Understanding the growth behavior of microorganisms using modeling and optimization techniques is an...
The need for the development of economic high plasmid production in Escherichia coli cultures is eme...
Clustered microbial communities are omnipresent in the food industry, e.g., as colonies of microbial...
The current production of a number of commodity chemicals relies on the exploitation of fossil fuels...