From Physics to Bioengineering: Microbial Cultivation Process Design and Feeding Rate Control Based on Relative Entropy Using Nuisance Time

Abstract: For historic reasons, industrial knowledge of reproducibility and restrictions imposed by regulations, open-loop feeding control approaches dominate in industrial fed-batch cultivation processes. In this study, a generic gray box biomass modeling procedure uses relative entropy as a key to approach the posterior similarly to how prior distribution approaches the posterior distribution by the multivariate path of Lagrange multipliers, for which a description of a nuisance time is introduced. The ultimate purpos… Show more

“…The posterior distribution for the m-th offline sample is: where every sampled prediction m has a constant variance σ 2 X . Prior distribution also has the form of Gaussian distribution [31,32]:…”

“…where X y m is the mth observation value of the biomass concentration and its individual variance is σ 2 X,m . Integration of relative entropy [31] yields:…”

“…where a further procedure neglects coefficient c. In a previous study [31], the uncertainty of prior distribution was set as equal to the squared observed value. However, Reference [3] showed that there are trade-offs between the least squares approach and the squared mean absolute percentage error (MAPE) criterion.…”

“…The tuning coefficient K exp 0 ≤ K exp ≤ 1 with a value of 1 recreates the least squares approach, which has a higher penalty for bigger criterion values. Meanwhile, the value of zero results in the squared MAPE criterion [31], which restricts estimation errors to smaller overall criterion values. Such criteria showed acceptable practical benefits in a generic case of a biomass model fitting procedure.…”

“…The process of identifying E. coli BL21 (DE3) pET28a strain's stoichiometric parameters and protein model fitting coefficients is based on the convex optimization method and the maximization of entropy [31,37]. Figure 2 depicts the workflow of the optimization procedure.…”

Identification of Functional Bioprocess Model for Recombinant E. Coli Cultivation Process

“…The posterior distribution for the m-th offline sample is: where every sampled prediction m has a constant variance σ 2 X . Prior distribution also has the form of Gaussian distribution [31,32]:…”

“…where X y m is the mth observation value of the biomass concentration and its individual variance is σ 2 X,m . Integration of relative entropy [31] yields:…”

“…where a further procedure neglects coefficient c. In a previous study [31], the uncertainty of prior distribution was set as equal to the squared observed value. However, Reference [3] showed that there are trade-offs between the least squares approach and the squared mean absolute percentage error (MAPE) criterion.…”

“…The tuning coefficient K exp 0 ≤ K exp ≤ 1 with a value of 1 recreates the least squares approach, which has a higher penalty for bigger criterion values. Meanwhile, the value of zero results in the squared MAPE criterion [31], which restricts estimation errors to smaller overall criterion values. Such criteria showed acceptable practical benefits in a generic case of a biomass model fitting procedure.…”

“…The process of identifying E. coli BL21 (DE3) pET28a strain's stoichiometric parameters and protein model fitting coefficients is based on the convex optimization method and the maximization of entropy [31,37]. Figure 2 depicts the workflow of the optimization procedure.…”

Identification of Functional Bioprocess Model for Recombinant E. Coli Cultivation Process

A novel normalized versatile based innovative controller for nonlinear biological systems

An oxygen-uptake-rate-based estimator of the specific growth rate in Escherichia coli BL21 strains cultivation processes