Model-Based Optimization of a Fed-Batch Bioreactor for mAb Production Using a Hybridoma Cell Culture

Production of monoclonal antibodies (mAbs) is a well-known method used to synthesize a large number of identical antibodies, which are molecules of huge importance in medicine. Due to such reasons, intense efforts have been invested to maximize the mAbs production in bioreactors with hybridoma cell cultures. However, the optimal control of such sensitive bioreactors is an engineering problem difficult to solve due to the large number of state-variables with highly nonlinear dynamics, which often translates into a non-convex optimization problem that involves a significant number of decision (control) variables. Based on an adequate kinetic model adopted from the literature, this paper focuses on developing an in-silico (model-based, offline) numerical analysis of a fed-batch bioreactor (FBR) with an immobilized hybridoma culture to determine its optimal feeding policy by considering a small number of control variables, thus ensuring maximization of mAbs production. The obtained time stepwise optimal feeding policies of FBR were proven to obtain better performances than those of simple batch operation (BR) for all the verified alternatives in terms of raw material consumption and mAbs productivity. Several elements of novelty (i–iv) are pointed out in the “conclusions” section (e.g., considering the continuously added biomass as a control variable during FBR).

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Model-based reinforcement learning and predictive control for two-stage optimal control of fed-batch bioreactor

Computers & Chemical Engineering ◽

10.1016/j.compchemeng.2021.107465 ◽

2021 ◽

pp. 107465

Author(s):

Jong Woo Kim ◽

Byung Jun Park ◽

Tae Hoon Oh ◽

Jong Min Lee

Keyword(s):

Optimal Control ◽

Reinforcement Learning ◽

Predictive Control ◽

Fed Batch ◽

Two Stage ◽

Model Based ◽

Batch Bioreactor

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In-silico Optimization of a Batch Bioreactor for mAbs Production in Relationship to the Net Evolution of the Hybridoma Cell Culture

Revista de Chimie ◽

10.37358/rc.19.8.7470 ◽

2019 ◽

Vol 70 (8) ◽

pp. 2985-2992

Author(s):

Gheorghe Maria ◽

Cristiana Luminita Gijiu ◽

Iulian Cebanu ◽

Cristina Maria ◽

Carmen Tociu

Keyword(s):

Cell Culture ◽

In Silico ◽

Operation Mode ◽

In Silico Analysis ◽

Operating Mode ◽

Optimal Operation ◽

Engineering Problem ◽

Batch Bioreactor ◽

Hybridoma Cell Culture ◽

Viable Biomass

Bioreactor optimization is a common engineering problem difficult to be solved due to the large number of influential variables of high variability. Production of monoclonal antibody is a well-known method to synthesize a large number of identical antibodies (that is of uniform characteristics, also called monoclonal antibodies, mAb). Due to such reasons intense efforts have been invested to maximize the production of mAb by using hybridoma cell culture. Based on an adequate kinetic model from literature (experimentally checked) this paper focus on pointing-out the major role of the net evolution of the viable biomass (growth, and decay) in the location of the optimal operating setpoint (SP) of a three-phase mechanically agitated batch bioreactor (TPMAB) with immobilized hybridoma culture. This in-silico analysis opens the possibility I) to optimize the bioreactor performances by placing the SP in the most favourable location, by adjusting the substrate and biomass initial load in the bioreactor according to the preliminary determined characteristics of a modified / improved biomass; ii) to optimize the batch-to-batch operation mode (not approached here) according to the time-varying characteristics of the biomass culture, or iii) to determine the optimal operation of the bioreactor in a fed-batch operating mode (not approached here).

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