Computational fluid dynamics simulation of an industrial P. chrysogenum fermentation with a coupled 9-pool metabolic model: Towards rational scale-down and design optimization

[Display omitted] •Metabolic-hydrodynamic simulation to predict yield loss due to substrate gradient.•Novel design approach for representative scale-down simulators.•Use of simulations to assess effect of reactor design on process yield.•Experimental verification of penicillin production rate in fed...

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Bibliographic Details
Published inChemical engineering science Vol. 175; pp. 12 - 24
Main Authors Haringa, Cees, Tang, Wenjun, Wang, Guan, Deshmukh, Amit T., van Winden, Wouter A., Chu, Ju, van Gulik, Walter M., Heijnen, Joseph J., Mudde, Robert F., Noorman, Henk J.
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 2018
Subjects
CFD
Euler-Langrange
Industrial
Metabolic model
Scale-down
CFD
76T10
Industrial
92-08
Metabolic model
Scale-down
Euler-Langrange
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Summary:[Display omitted] •Metabolic-hydrodynamic simulation to predict yield loss due to substrate gradient.•Novel design approach for representative scale-down simulators.•Use of simulations to assess effect of reactor design on process yield.•Experimental verification of penicillin production rate in fed-batch simulation.•Prediction of emerging population heterogeneity in fed-batch simulation. We assess the effect of substrate heterogeneity on the metabolic response of P. chrysogenum in industrial bioreactors via the coupling of a 9-pool metabolic model with Euler-Lagrange CFD simulations. In this work, we outline how this coupled hydrodynamic-metabolic modeling can be utilized in 5 steps. (1) A model response study with a fixed spatial extra-cellular glucose concentration gradient, which reveals a drop in penicillin production rate qp of 18–50% for the simulated reactor, depending on model setup. (2) CFD-based scale-down design, where we design a 1-vessel scale down simulator based on the organism lifelines. (3) Scale-down verification, numerically comparing the model response in the proposed scale-down simulator with large-scale CFD response. (4) Reactor design optimization, reducing the drop in penicillin production by a change of feed location. (5) Long-term fed-batch simulation, where we verify model predictions against experimental data, and discuss population heterogeneity. Overall, these steps present a coupled hydrodynamic-metabolic approach towards bioreactor evaluation, scale-down and optimization.
ISSN:0009-2509
1873-4405
DOI:10.1016/j.ces.2017.09.020