Experimental Validation of a Cascade Control Strategy for Continuously Perfused Animal Cell Cultures

Abbate, Thomas; Sbarciog, Mihaela; Dewasme, Laurent; Wouwer, Alain Vande

doi:10.3390/pr8040413

Cited by 7 publications

(8 citation statements)

References 28 publications

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“…Run 9 exhibits profiles of slightly lower concentrations for Asn, Thr, Pro and Lys, although these profiles seem almost parallel to the ones of run 10. The profiles of concentrations His, Thr, Met, Val, Ile, Leu, Phe and Trp diverge and exhibit an increasing difference between run 9 and 10 towards day 2 [23]. However, all of these differences seem to fall within typically encountered biological and analytical variation.…”

Section: Qualitative Performance Assessmentmentioning

confidence: 80%

“…Comparing the triplicate runs 1 to 3, it strikes that run 3 shows significantly increased flux values for reactions 8 to 13 though slightly lower values for reaction 14. The third run exhibits a significantly lower concentrations profile for Asp [23], which might, in combination with the slight increases in the fluxes of reactions 23, 30 and 40, explain the difference. In case of the replicate runs 9 and 10, the trends between the fluxes of t1-t0 and t2-t1 are reversed.…”

Section: Qualitative Performance Assessmentmentioning

confidence: 90%

See 1 more Smart Citation

Time Integrated Flux Analysis: Exploiting the Concentration Measurements Directly for Cost-Effective Metabolic Network Flux Analysis

Portela¹,

Richelle²,

Dumas³

et al. 2019

Microorganisms

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Background: Flux analyses, such as Metabolic Flux Analysis (MFA), Flux Balance Analysis (FBA), Flux Variability Analysis (FVA) or similar methods, can provide insights into the cellular metabolism, especially in combination with experimental data. The most common integration of extracellular concentration data requires the estimation of the specific fluxes (/rates) from the measured concentrations. This is a time-consuming, mathematically ill-conditioned inverse problem, raising high requirements for the quality and quantity of data. Method: In this contribution, a time integrated flux analysis approach is proposed which avoids the error-prone estimation of specific flux values. The approach is adopted for a Metabolic time integrated Flux Analysis and (sparse) time integrated Flux Balance/Variability Analysis. The proposed approach is applied to three case studies: (1) a simulated bioprocess case studying the impact of the number of samples (experimental points) and measurements’ noise on the performance; (2) a simulation case to understand the impact of network redundancies and reaction irreversibility; and (3) an experimental bioprocess case study, showing its relevance for practical applications. Results: It is observed that this method can successfully estimate the time integrated flux values, even with relatively low numbers of samples and significant noise levels. In addition, the method allows the integration of additional constraints (e.g., bounds on the estimated concentrations) and since it eliminates the need for estimating fluxes from measured concentrations, it significantly reduces the workload while providing about the same level of insight into the metabolism as classic flux analysis methods.

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Section: Qualitative Performance Assessmentmentioning

confidence: 80%

Section: Qualitative Performance Assessmentmentioning

confidence: 90%

Time Integrated Flux Analysis: Exploiting the Concentration Measurements Directly for Cost-Effective Metabolic Network Flux Analysis

Portela¹,

Richelle²,

Dumas³

et al. 2019

Microorganisms

View full text Add to dashboard Cite

show abstract

“…Essential to maintaining the balance between DO, pCO 2 accumulation, and foam generation is establishing bioreactor‐specific relationships for the parameters that govern this balance, including the gas transfer (i.e., k L a) for a given gas species and sparger design. Therefore, it is essential for perfusion bioreactor control architecture to permit the use of reasonably complex algorithms (Abbate et al, 2020 ) to manage these three control elements, as well as the ability to incorporate so‐called offline, at‐line, and online measurements such as cell density, temperature, lactic acid concentration, glucose concentration, and pH.…”

Section: Resultsmentioning

confidence: 99%

The design basis for the integrated and continuous biomanufacturing framework

Coffman

Bibbo²,

Brower

et al. 2021

Biotech & Bioengineering

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An 8 ton per year manufacturing facility is described based on the framework for integrated and continuous bioprocessing (ICB) common to all known biopharmaceutical implementations. While the output of this plant rivals some of the largest fed‐batch plants in the world, the equipment inside the plant is relatively small: the plant consists of four 2000 L single‐use bioreactors and has a maximum flow rate of 13 L/min. The equipment and facility for the ICB framework is described in sufficient detail to allow biopharmaceutical companies, vendors, contract manufacturers to build or buy their own systems. The design will allow the creation of a global ICB ecosystem that will transform biopharmaceutical manufacturing. The design is fully backward compatible with legacy fed‐batch processes. A clinical production scale is described that can produce smaller batch sizes with the same equipment as that used at the commercial scale. The design described allows the production of as little as 10 g to nearly 35 kg of drug substance per day.

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“…For example, the metabolism of animal cells is complex and can be influenced by various mechanisms of metabolite activation. Predictive control strategies can be used to better emulate this biological complexity [23,35]. Besides the transient nature of animal cell culture bioprocesses, Zupke et al also mentions interactions between CQAs and their control levers and delays associated with analytics as strong drivers for MPC [27].…”

Section: Discussionmentioning

confidence: 99%

“…Use of the MPC control scheme, in which a mathematical model is used to predict its future trajectory, can minimize the generated error signal. This has been addressed, for example, by novel control schemes in perfusion and continuous systems [ 23 , 24 ] by supporting continuous bio production in downstream purifications [ 25 ] or by controlling product quality attributes in antibody manufacture [ 26 , 27 ]. A so-called single prediction controller (SPC) anticipates the future behavior based on only one prediction of the system output.…”

Section: Introductionmentioning

confidence: 99%

Model predictive control for steady-state performance in integrated continuous bioprocesses

Pappenreiter

Döbele²,

Striedner

et al. 2022

Bioprocess Biosyst Eng

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Perfusion bioreactors are commonly used for the continuous production of monoclonal antibodies (mAb). One potential benefit of continuous bioprocessing is the ability to operate under steady-state conditions for an extended process time. However, the process performance is often limited by the feedback control of feed, harvest, and bleed flow rates. If the future behavior of a bioprocess can be adequately described, predictive control can reduce set point deviations and thereby maximize process stability. In this study, we investigated the predictive control of biomass in a perfusion bioreactor integrated to a non-chromatographic capture step, in a series of Monte-Carlo simulations. A simple algorithm was developed to estimate the current and predict the future viable cell concentrations (VCC) of the bioprocess. This feature enabled the single prediction controller (SPC) to compensate for process variations that would normally be transported to adjacent units in integrated continuous bioprocesses (ICB). Use of this SPC strategy significantly reduced biomass, product concentration, and harvest flow variability and stabilized the operation over long periods of time compared to simulations using feedback control strategies. Additionally, we demonstrated the possibility of maximizing product yields simply by adjusting perfusion control strategies. This method could be used to prevent savings in total product losses of 4.5–10% over 30 days of protein production.

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Experimental Validation of a Cascade Control Strategy for Continuously Perfused Animal Cell Cultures

Cited by 7 publications

References 28 publications

Time Integrated Flux Analysis: Exploiting the Concentration Measurements Directly for Cost-Effective Metabolic Network Flux Analysis

Time Integrated Flux Analysis: Exploiting the Concentration Measurements Directly for Cost-Effective Metabolic Network Flux Analysis

The design basis for the integrated and continuous biomanufacturing framework

Model predictive control for steady-state performance in integrated continuous bioprocesses

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