State estimation and predictive control of fed-batch cultures of hybridoma cells

Dewasme, Laurent; Afonso Fernandes, Sofia; Amribt, Zakaria; Santos, Lino; Bogaerts, Philippe; Vande Wouwer, Alain

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State estimation and predictive control of fed-batch cultures of hybridoma cells

Dewasme, Laurent; Afonso Fernandes, Sofia; Amribt, Zakaria et al.

2015 • In Journal of Process Control, 30, p. 50-57

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Research center :

BIOSYS - Biosys

Disciplines :

Electrical & electronics engineering
Biotechnology

Author, co-author :

Dewasme, Laurent ; Université de Mons > Faculté Polytechnique > Systèmes, Estimation, Commande et Optimisation

Afonso Fernandes, Sofia ; Université de Mons > Faculté Polytechnique > Systèmes, Estimation, Commande et Optimisation

Amribt, Zakaria

Santos, Lino

Bogaerts, Philippe

Vande Wouwer, Alain ; Université de Mons > Faculté Polytechnique > Service Systèmes, Estimation, Commande et Optimisation

Language :

English

Title :

State estimation and predictive control of fed-batch cultures of hybridoma cells

Publication date :

22 January 2015

Journal title :

Journal of Process Control

ISSN :

0959-1524

Publisher :

Butterworth Scientific, United Kingdom

Volume :

Pages :

50-57

Peer reviewed :

Peer Reviewed verified by ORBi

Research unit :

F107 - Systèmes, Estimation, Commande et Optimisation

Research institute :

R100 - Institut des Biosciences

Available on ORBi UMONS :

since 20 August 2014

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Bibliography

[1] de Tremblay, M., Perrier, M., Chavarie, C., Archambault, J., Optimization of fed-batch culture of hybridoma cells using dynamic programming: single and multi-feed cases. Bioprocess. Biosyst. Eng. 7:5 (1992), 229–234.
[2] Dhir, S.K.J.M. Jr., Rhinehart, R.R., Wiesne, T., Dynamic optimization of hybridoma growth in a fed-batch bioreactor. Biotechnol. Bioeng. 67:2 (2000), 197–205.
[3] Amribt, Z., Niu, H., Bogaerts, P., Macroscopic modelling of overflow metabolism and model based optimization of hybridoma cell fed-batch cultures. Biochem. Eng. J. 70 (2013), 196–209.
[4] Dewasme, L., Amribt, Z., Santos, L.-O., Hantson, A.-L., Bogaerts, P., Vande Wouwer, A., Hybridoma cell culture optimization using nonlinear model predictive control. 12th IFAC Symposium on Computer Applications in Biotechnology (CAB 2013), 2013.
[5] Pomerleau, Y., Modélisation et commande d'un procédé fed-batch de culture des levures pain. (Ph.D. thesis), 1990, Département de génie chimique, Université de Montréal.
[6] Akesson, M., Probing control of glucose feeding in Escherichia coli cultivations. (Ph.D. thesis), 1999, Lund Institute of Technology, Sweden.
[7] Dewasme, L., Richelle, A., Dehottay, P., Georges, P., Remy, M., Bogaerts, P., Vande Wouwer, A., Linear robust control of S. cerevisiae fed-batch cultures at different scales. Biochem. Eng. J. 53:1 (2010), 26–37.
[8] Santos, L.-O., Dewasme, L., Coutinho, D., Vande Wouwer, A., Nonlinear model predictive control of fed-batch cultures of micro-organisms exhibiting overflow metabolism: Assessment and robustness. Comput. Chem. Eng. 39 (2012), 143–151.
[9] Qin, S.J., Badgwell, T.A., A survey of industrial model predictive control technology. Control Eng. Pract. 11 (2003), 733–764.
[10] Lee, J.H., Model predictive control: review of the three decades of development. Int. J. Control Autom. Syst. 9:3 (2011), 415–424.
[11] Nagy, Z., Braatz, R.D., Robust nonlinear model predictive control of batch processes. AIChE J. 249:7 (2003), 1776–1786.
[12] Nagy, Z.K., Braatz, R.D., Open-loop and closed-loop robust optimal control of batch processes using distributional and worst-case analysis. J. Process Control 14:4 (2004), 411–422.
[13] Magni, L., Raimondo, D.M., Allgöwer, F., (eds.) Nonlinear Model Predictive Control – Towards New Challenging Applications, Vol. 384 of Lecture Notes in Control and Information Sciences, 2009, Springer, Berlin.
[14] Amribt, Z., Dewasme, L., Vande Wouwer, A., Bogaerts, P., Optimization and robustness analysis of hybridoma cell fed-batch cultures using the overflow metabolism model. Bioprocess Biosyst. Eng. 37 (2014), 1637–1652.
[15] Hitzmann, B., Broxtermann, O., Cha, Y.-L., Sobieh, O., Strk, E., Scheper, T., The control of glucose concentration during yeast fed-batch cultivation using a fast measurement complemented by an extended Kalman filter. Bioprocess. Eng. 23 (2000), 337–341.
[16] Arndt, M., Hitzmann, B., Kalman filter based glucose control at small set points during fed-batch cultivation of saccharomyces cerevisiae. Biotechnol. Progr. 20 (2004), 377–383.
[17] Arndt, M., Kleist, S., Miksch, G., Friehs, K., Flaschel, E., Trierweiler, J., Hitzmann, B., A feedforward–feedback substrate controller based on a Kalman filter for a fed-batch cultivation of Escherichia coli producing phytase. Comput. Chem. Eng. 29 (2005), 1113–1120.
[18] Veloso, A.C.A., Rocha, I., Ferreira, E.C., Monitoring of fed-batch E. coli fermentations with software sensors. Bioprocess Biosyst. Eng. 32 (2009), 381–388.
[19] Dewasme, L., Goffaux, G., Hantson, A.-L., Vande Wouwer, A., Experimental validation of an extended Kalman filter estimating acetate concentration in E. coli cultures. J. Process Control 23 (2013), 148–157.
[20] Sonnleitner, B., Käppeli, O., Growth of Saccharomyces cerevisiae is controlled by its limited respiratory capacity: formulation and verification of a hypothesis. Biotechnol. Bioeng. 28 (1986), 927–937.
[21] Dochain, D., Vanrolleghem, P., Identification of Bioprocess Models. 2008, ISTE Ltd./John Wiley and Sons Inc., Great Britain/United States.
[22] Axelsson, J.P., Modeling and control of fermentation processes. (Ph.D. thesis), 1989, Lund Institute of Technology, Sweden.
[23] Raimondo, D.M., Limon, D., Lazar, M., Magni, L., Camacho, E.F., Min–max model predictive control of nonlinear systems: a unifying overview on stability. Eur. J. Control 15:1 (2009), 5–21.
[24] Lucia, S., Finkler, T., Engell, S., Multi-stage nonlinear model predictive control applied to a semi-batch polymerization reactor under uncertainty. J. Process Control 23:9 (2013), 1306–1319.
[25] Huang, R., Patwardhan, S.C., Biegler, L.T., Robust stability of nonlinear model predictive control based on extended Kalman filter. J. Process Control 22:1 (2012), 82–89.
[26] Riley, M.R., Rhiel, M., Zhou, X., Arnold, M.A., Murhammer, D.W., Simultaneous measurement of glucose and glutamine in insect cell culture media by near infrared spectroscopy. Biotechnol. Bioeng. 55:1 (1997), 11–15.
[27] Zeitz, M., Observability canonical (phase-variable) form for nonlinear time-variable systems. Int. J. Syst. Sci. 15:9 (1984), 949–958.
[28] Gauthier, J.-P., Kupka, I., Observability and observers for nonlinear systems. SIAM J. Control Optim. 32:4 (1994), 975–994.
[29] Amribt, Z., Dewasme, L., Vande Wouwer, A., Bogaerts, P., Parameter identification for state estimation: design of an extended Kalman filter for hybridoma cell fed-batch cultures. 19th IFAC World Congress (IFAC’14), 2014.
[30] Bogaerts, P., Vande Wouwer, A., Parameter identification for state estimation – application to bioprocess software sensors. Chem. Eng. Sci. 59:12 (2004), 2465–2476.
[31] Julier, S.J., Uhlmann, J.K., A new extension of the Kalman filter to nonlinear systems. Proceedings of AeroSense: 11th International Symposium Aerospace/Defense Sensing, Simulation and Controls, 1997, 182–193.
[32] Julier, S.J., Uhlmann, J.K., Unscented filtering and nonlinear estimation. Proc. IEEE 92:3 (2004), 401–422.
[33] Kandepu, R., Foss, B., Imsland, L., Applying the unscented Kalman filter for nonlinear state estimation. J. Process Control 18:7–8 (2008), 753–768.