Mammalian Cell Culture Process for Monoclonal Antibody Production: Nonlinear Modelling and Parameter Estimation

Selişteanu, Dan; Şendrescu, Dorin; Georgeanu, Vlad Alexandru; Roman, Monica

doi:10.1155/2015/598721

Cited by 30 publications

(24 citation statements)

References 52 publications

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“…Majority of biopharmaceutical drugs are produced by Chinese hamster ovary (CHO) cells, which have remained the standard industry host for the past three decades [4]. CHO cells are predominantly used as expression hosts for recombinant monoclonal antibody (mAb) production [1,5], which is also the fastest growing segment of the biopharmaceutical industry [6]. The reason for this wide use of CHO cells is mainly their ability to perform post-translational modifications and correctly fold recombinant proteins, as well as their proven track-record of being safe hosts [4,5].…”

Section: Introductionmentioning

confidence: 99%

“…Two common experimental strategies used for this purpose are statistical design, which allows for statistical analysis and control of external variables, and metabolic profiling, which provides information on the physiology of the cell. These types of experimental methods can often be resource-intensive and require large amount of experiments [6]. Therefore, there is emerging interest in using modelling approaches to assist and guide the laboratory experiments to achieve further improvements.…”

Section: Introductionmentioning

confidence: 99%

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Amino Acid Requirements of the Chinese Hamster Ovary Cell Metabolism during Recombinant Protein Production

Traustason

2019

Preprint

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Majority of biopharmaceutical drugs today are produced by Chinese hamster ovary (CHO) cells, which have been the standard industry host for the past decades. To produce and secrete a substantial amount of the target recombinant proteins the CHO cells must be provided with suitable growth conditions and provided with the necessary nutrients. Amino acids play a key role in this as the building blocks of proteins, playing important roles in a large number of metabolic pathways and being important sources of nitrogen as well as carbon under certain conditions. In this study exploratory analysis of the amino acid requirements of CHO cells was carried out using metabolic modelling approaches. Flux balance analysis was employed to evaluate the optimal distribution of fluxes in a genome-scale model of CHO cells to gain information on the cells' metabolic response in silico.The results showed that providing non-essential amino acids (NEAAs) has a positive effect on CHO cell biomass production and that cysteine as well as tyrosine play a fundamental role in this.This implies that extracellular provision of NEAAs limits the extent of energy loss in amino acid biosynthetic pathways and renders additional reducing power available for other biological processes.Detailed analysis of the possible secretion and uptake of D-serine in the CHO model was also performed and its influence on the rest of the metabolism mapped out, which revealed results matching various existing literature. This is interesting since no mention of D-serine in regard to CHO cells was found in current literature, as well as the fact that this opens up the possibility of using the model for better understanding of certain disorders in higher up organisms that have been implicated with D-serine, such as motor neuron and cognitive degeneration. Finally, outcome from the model optimisation of different recombinant proteins demonstrated clearly how the difference in protein structure and size can influence the production outcome. These results show that systematic and model-based approaches have great potential for broad de novo exploration as well as being able to handle the cellular burden associated with the production of different types of recombinant protein.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Amino Acid Requirements of the Chinese Hamster Ovary Cell Metabolism during Recombinant Protein Production

Traustason

2019

Preprint

View full text Add to dashboard Cite

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“…Here, it should be highlighted that although some kinetic models include detailed metabolic reaction kinetics, they are clearly different from static metabolic flux‐based models (see Terminology), which can be constructed based on reaction stoichiometry without considering enzyme kinetics . These flux models reduce the metabolite mass balances to linear algebraic equations by assuming steady state with no accumulation, and thus can be solved easily unlike kinetic models comprising non‐linear equations, which often require more complicated solution procedures . Despite such complexity, kinetic modeling is, however, the most suitable approach to characterize the dynamic behavior of mammalian cell cultures in terms of cellular growth and metabolic utilization .…”

Section: Introductionmentioning

confidence: 99%

“…[6,7] These flux models reduce the metabolite mass balances to linear algebraic equations by assuming steady state with no accumulation, [8,9] and thus can be solved easily unlike kinetic models comprising non-linear equations, which often require more complicated solution procedures. [10] Despite such complexity, kinetic modeling is, however, the most suitable approach to characterize the dynamic behavior of mammalian cell cultures in terms of cellular growth and metabolic utilization. [11] The model quality can be further enhanced through the validation of models which can be iteratively refined by reducing the discrepancy between model predictions and experimentally observed states.…”

Section: Introductionmentioning

confidence: 99%

Kinetic Modeling of Mammalian Cell Culture Bioprocessing: The Quest to Advance Biomanufacturing

Kyriakopoulos

Ang

Huang

et al. 2017

Biotechnology Journal

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Kinetic modeling is the most suitable framework to describe the dynamic behavior of mammalian cell culture although its industrial application is still in its infancy. Herein, the authors reviewed mammalian bioprocess relevant kinetic models, and found that the simple unstructured-unsegregated approach utilizing empirical Monod-type kinetics based on limiting substrates and inhibitory metabolites is commonly used due to its traceability and simple formalism. Notably, the available kinetic models are typically small to moderate in size, and the development of large-scale models is severely hampered by the scarcity of kinetic data and limitations in current parameter estimation methods. The recent availability of abundant high-throughput multi-omics datasets from mammalian cell cultures have now paved the way to improve parameterization of kinetic models, and integrate regulatory, signaling, and product quality related intracellular events, as well as cellular metabolism within the modeling framework. Ultimately, the authors foresee that multi-scale modeling is the way forward in building predictive kinetic models of mammalian cell culture to advance biomanufacturing.

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“…Liu et al [13] presented a method for estimating one-dimensional discrete chaotic system based on mean value function. In addition, some intelligent optimization algorithms have been proposed for the parameter identification, such as genetic algorithm (GA) [14], particle swarm optimization (PSO) [15][16][17][18], differential evolution (DE) [19], ant swarm optimization algorithm (AS) [20], bat algorithm (BA) [21], cuckoo search optimization algorithm (CS) [22], and teaching learning based optimization (TLBO) [23]. However, research on the influence of time series on the estimation accuracy of multidimensional nonlinear system is rare.…”

Section: Introductionmentioning

confidence: 99%

A Parameter Estimation Method for Nonlinear Systems Based on Improved Boundary Chicken Swarm Optimization

Chen

Yang

et al. 2016

Discrete Dynamics in Nature and Society

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Parameter estimation is an important problem in nonlinear system modeling and control. Through constructing an appropriate fitness function, parameter estimation of system could be converted to a multidimensional parameter optimization problem. As a novel swarm intelligence algorithm, chicken swarm optimization (CSO) has attracted much attention owing to its good global convergence and robustness. In this paper, a method based on improved boundary chicken swarm optimization (IBCSO) is proposed for parameter estimation of nonlinear systems, demonstrated and tested by Lorenz system and a coupling motor system. Furthermore, we have analyzed the influence of time series on the estimation accuracy. Computer simulation results show it is feasible and with desirable performance for parameter estimation of nonlinear systems.

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Mammalian Cell Culture Process for Monoclonal Antibody Production: Nonlinear Modelling and Parameter Estimation

Cited by 30 publications

References 52 publications

Amino Acid Requirements of the Chinese Hamster Ovary Cell Metabolism during Recombinant Protein Production

Amino Acid Requirements of the Chinese Hamster Ovary Cell Metabolism during Recombinant Protein Production

Kinetic Modeling of Mammalian Cell Culture Bioprocessing: The Quest to Advance Biomanufacturing

A Parameter Estimation Method for Nonlinear Systems Based on Improved Boundary Chicken Swarm Optimization

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