Interactive Multi‐objective Dynamic Optimization of Bioreactors under Parametric Uncertainty

Nimmegeers, Philippe; Vallerio, Mattia; Telen, Dries; Impe, Jan Van; Logist, Filip

doi:10.1002/cite.201800082

Cited by 18 publications

(10 citation statements)

References 36 publications

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“…23 These uncertainties can arise due to several factors such as parameter estimation using noisy data, external process disturbances, high degree of nonlinearity, limited experimental data causing model identifiability problems, model assumptions, etc. 23 Thus, incorporation of such uncertainties is important while performing the optimization in order to obtain robust control profiles (i.e., manipulated variables during the process), which guarantee better objective estimates without violation of any constraints. In the literature, a number of approaches for handling uncertainty while performing optimization have been reported.…”

Section: Introductionmentioning

confidence: 99%

“…Although such a modeling and optimization exercise can offer significant advantages for large-scale process development, in practice, this analysis can lead to suboptimal or even infeasible estimates without considering the uncertainties which are inherently present in the model . These uncertainties can arise due to several factors such as parameter estimation using noisy data, external process disturbances, high degree of nonlinearity, limited experimental data causing model identifiability problems, model assumptions, etc .…”

Section: Introductionmentioning

confidence: 99%

“…Optimization under uncertainty has also been applied for other biological processes. ,− Liu et al applied the concepts of parametric uncertainty for ensemble modeling of a hybridoma cell culture for maximizing monoclonal antibody production . Optimization under uncertainty has also been performed for various biochemical networks with single objectives as well as the conflicting objectives of minimizing the energy consumption while maximizing the production of a specific metabolite. , Logist et al applied multiobjective dynamic optimization for the optimal design and operation of a jacketed tubular reactor and a fed-batch bioreactor with conflicting objectives .…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Toward Performance Improvement of a Baculovirus–Insect Cell System under Uncertain Environment: A Robust Multiobjective Dynamic Optimization Approach for Semibatch Suspension Culture

Sharma

Keerthi

Giri

et al. 2022

Ind. Eng. Chem. Res.

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The baculovirus expression vector system (BEVS) is one of the well-known versatile platforms for the recombinant protein/vaccine production. Mathematical modeling and optimization of a baculovirus−insect cell system can have significant industrial relevance as this reduces the number of expensive experiments and time involved in the experiment-based optimization. However, modeling and control of such a nonlinear system remains challenging due to the presence of uncertainties in the model. In this context, we propose a novel computational framework combining the principles of systems biology and dynamic optimization under uncertainty for optimizing a semibatch baculovirus− insect cell system. Toward this, first, a mathematical model replicating the dynamic experimental data on cell and virus growth was identified. Next, the proposed model was used for deterministic multiobjective dynamic optimization of the control variables, substrate, and multiplicity of infection (MOI) to achieve the conflicting objectives of productivity maximization and substrate minimization, simultaneously. Finally, based on the sensitivity analysis, six of the most influential parameters depicting model uncertainties have been considered for the robust multiobjective optimal control of the system. A comprehensive comparison displays up to 114% and 76% increases in the cell densities for the deterministic and stochastic semibatch processes, respectively, compared to the batch process. Semibatch operation also favors a minimum 40% reduction in MOI required to achieve the same level of infected cell density compared to the batch operation. This study provides a generic methodology for exhibiting a proof of concept that a semibatch suspension culture considering uncertainty in model parameters can give better productivity compared to a batch suspension culture for a BEVS.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Toward Performance Improvement of a Baculovirus–Insect Cell System under Uncertain Environment: A Robust Multiobjective Dynamic Optimization Approach for Semibatch Suspension Culture

Sharma

Keerthi

Giri

et al. 2022

Ind. Eng. Chem. Res.

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show abstract

“…MOO has attracted increasing number of applications in chemical engineering. 2 Recent papers on MOO applications by active researchers in process systems engineering are design and control of intensified distillation sequence, 4 model simulation of ethylene oxide formation in a packed bed membrane reactor, 5 energy system design for a commercial building, 6 resilient design and operation of process systems, 7 generation of rule-based classifier for categorical data, 8 design of solid oxide fuel cell with a gas turbine hybrid system, 9 design of biomass supply chains, 10 interactive MOO of biochemical processes with parametric uncertainty, 11 design of carbonhydrogen-oxygen symbiosis networks, 12 sustainable water management, 13 and batch distillation optimization for economic and environmental objectives. 14 Our group has been active in MOO research for about 2 decades and has contributed two books 15,16 and many articles on MOO and its applications.…”

Section: Introductionmentioning

confidence: 99%

Analysis of Weighting and Selection Methods for Pareto-Optimal Solutions of Multiobjective Optimization in Chemical Engineering Applications

Wang

Parhi

Rangaiah

et al. 2020

Ind. Eng. Chem. Res.

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Optimization in chemical engineering often involves two or more objectives, which are conflicting. Multiobjective optimization (MOO) generates a set of equally good solutions from the perspective of objectives used; these solutions are known as nondominated or Paretooptimal solutions. Although MOO has become popular in chemical engineering in the past 20 years, majority of studies are limited to finding Pareto-optimal solutions and only some papers discussed the selection of one nondominated solution for implementation. Thus, the main research gap in the application of MOO in chemical engineering is the very limited use of selection or ranking methods. To address this gap, 8 weighting methods and 4 more selection methods (besides 10 methods analyzed by Wang and Rangaiah) are carefully chosen and implemented in an MS Excel-based program. Then, all these methods are applied to 12 mathematical and 13 chemical engineering problems. The results of this extensive analysis indicate that the entropy method, criteria importance through intercriteria correlation method, and best− worst method are better for determining weights for objectives. Further, out of the four additional selection methods tested, multiattributive border approximation area comparison is suggested for ranking Pareto-optimal solutions.

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“…Also, in recent years, some effort has been focused on accounting for model uncertainty during bioprocess optimization and control, as the cases of Liu and Gunawan (2017), Bradford, Schweidtmann, Zhang, Jing, and del Rio-Chanona (2018), Pantano, Fernández, Serrano, Ortiz, and Scaglia (2018), Nimmegeers, Vallerio, Telen, Van Impe, and Logist (2019) and Neba, Tornyeviadzi, Østerhus, and Seidu (2019). All these new developments show that quantifying the uncertainty of a kinetic model is key on its applicability for process design.…”

mentioning

confidence: 99%

Making sense of parameter estimation and model simulation in bioprocesses

Sadino-Riquelme

Rivas

Jeison

et al. 2020

Biotech & Bioengineering

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Most articles that report fitted parameters for kinetic models do not include meaningful statistical information. This study demonstrates the importance of reporting a complete statistical analysis and shows a methodology to perform it, using functionalities implemented in computational tools. As an example, alginate production is studied in a batch stirred‐tank fermenter and modeled using the kinetic model proposed by Klimek and Ollis (1980). The model parameters and their 95% confidence intervals are estimated by nonlinear regression. The significance of the parameters value is checked using a hypothesis test. The uncertainty of the parameters is propagated to the output model variables through prediction intervals, showing that the kinetic model of Klimek and Ollis (1980) can simulate with high certainty the dynamic of the alginate production process. Finally, the results obtained in other studies are compared to show how the lack of statistical analysis can hold back a deeper understanding about bioprocesses.

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Interactive Multi‐objective Dynamic Optimization of Bioreactors under Parametric Uncertainty

Cited by 18 publications

References 36 publications

Toward Performance Improvement of a Baculovirus–Insect Cell System under Uncertain Environment: A Robust Multiobjective Dynamic Optimization Approach for Semibatch Suspension Culture

Toward Performance Improvement of a Baculovirus–Insect Cell System under Uncertain Environment: A Robust Multiobjective Dynamic Optimization Approach for Semibatch Suspension Culture

Analysis of Weighting and Selection Methods for Pareto-Optimal Solutions of Multiobjective Optimization in Chemical Engineering Applications

Making sense of parameter estimation and model simulation in bioprocesses

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