Comparison of physics‐based and data‐driven modelling techniques for dynamic optimisation of fed‐batch bioprocesses

Rio‐Chanona, Ehecatl Antonio del; Ahmed, Nur Rashid; Wagner, Jonathan L.; Lu, Yinghua; Zhang, Dongda; Jing, Keju

doi:10.1002/bit.27131

Cited by 28 publications

(11 citation statements)

References 31 publications

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“…Biological microalgae models can help to estimate and maximize crop productivity Béchet et al (2016), as well as characteristic parameters that can be used in control systems to maximize biomass production (Costache et al, 2013; DelRio‐Chanona, Ahmed, et al, 2019; Pawlowski et al, 2015). However, although there exist some studies combining the microalgae productivity and culture temperature (Bernard & Rémond, 2012; James & Boriah, 2010), most existing biological models do not take the culture temperature into account, what is a limiting factor in the analysis of the microalgae productivity results (Huesemann et al, 2016; Karemore et al, 2020; Ras et al, 2013; Singh & Singh, 2015).…”

Section: Introductionmentioning

confidence: 99%

A new model to analyze the temperature effect on the microalgae performance at large scale raceway reactors

Rodríguez-Miranda

Acién

Guzmán

et al. 2020

Biotech & Bioengineering

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In this study a simplified temperature model for raceway reactors is developed, allowing to determine the temperature of the microalgae culture as a function of reactor design and environmental conditions. The model considers the major phenomena taking place in raceway reactors, especially heat absorption by radiation and heat losses by evaporation among others. The characteristic parameters of the model have been calibrated using genetic algorithms, next being validated with a long set of more than 50 days covering different weather conditions. It is worth to highlight the use of the developed model as a tool to analyze the influence of the temperature on the performance of microalgae cultures at large scale. As example, the annual variation of the performance of up to five different microalgae strains has been determined by computing the temperature index, thus the normalized value of performance of whatever microalgae at the real temperature with respect to that achievable at optimal temperature can be established. Results confirm that only strains tolerant to wide ranges of temperature can be efficiently produced all the year around in large scale outdoor raceway reactors without additional temperature control systems.

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Section: Introductionmentioning

confidence: 99%

A new model to analyze the temperature effect on the microalgae performance at large scale raceway reactors

Rodríguez-Miranda

Acién

Guzmán

et al. 2020

Biotech & Bioengineering

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“…Increasing incident light intensity (offsetting light attenuation) and enhancing culture mixing (shortening light/dark cycles) are two strategies to facilitate biomass growth in a PBR (Schulze et al, 2020). Although model‐based optimal control of light intensity has been reported previously (Del Rio‐Chanona et al, 2019; Koller et al, 2017), optimal control of gas inflow rate to enhance culture mixing has never been achieved as such a model was never proposed before.…”

Section: Resultsmentioning

confidence: 99%

“…Although model-based optimal control of light intensity has been reported previously (Del Rio-Chanona et al, 2019;Koller et al, 2017), optimal control of gas inflow rate to enhance culture mixing has never been achieved as such a model was never proposed before.…”

Section: Controlling Pbr Operationmentioning

confidence: 99%

Synergising biomass growth kinetics and transport mechanisms to simulate light/dark cycle effects on photo‐production systems

Cho

Servia

Chanona

et al. 2021

Biotech & Bioengineering

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Light attenuation is a primary challenge limiting the upscaling of photobioreactors for sustainable bio‐production. One key to this challenge, is to model and optimise the light/dark cycles so that cells within the dark region can be frequently transferred to the light region for photosynthesis. Therefore, this study proposes the first mechanistic model to integrate the light/dark cycle effects into biomass growth kinetics. This model was initially constructed through theoretical derivation based on the intracellular reaction kinetics, and was subsequently modified by embedding a new parameter, effective light coefficient, to account for the effects of culture mixing. To generate in silico process data, a new multiscale reactive transport modelling strategy was developed to couple fluid dynamics with biomass growth kinetics and light transmission. By comparing against previous experimental and computational studies, the multiscale model shows to be of high accuracy. Based on its simulation result, an original correlation was proposed to link effective light coefficient with photobioreactor gas inflow rate; this has not been done before. The impact of this study is that by using the proposed mechanistic model and correlation, we can easily control and optimise photobioreactor gas inflow rates to alleviate light attenuation and maintain a high biomass growth rate.

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“…11 Modeling, optimization, and state estimation of fed-batch systems have been successfully performed using kinetic models. 12 However, the predictive capacities of these models are usually low due to the reduction of a vast number of metabolic reactions into a few parameters and small sets of differential equations; any changes in the base conditions may have significant effects on model accuracy. 10 Data based models have been used as an alternative to kinetic based models in recent years because they can better predict a wide range of untested conditions than kinetic models because they use larger datasets that are valid for a wider spectrum of operating conditions and more variables for better description of the characteristics and behavior of the process.…”

Section: Introductionmentioning

confidence: 99%

Machine learning for algal biofuels: a critical review and perspective for the future

2023

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Comparison of physics‐based and data‐driven modelling techniques for dynamic optimisation of fed‐batch bioprocesses

Cited by 28 publications

References 31 publications

A new model to analyze the temperature effect on the microalgae performance at large scale raceway reactors

A new model to analyze the temperature effect on the microalgae performance at large scale raceway reactors

Synergising biomass growth kinetics and transport mechanisms to simulate light/dark cycle effects on photo‐production systems

Machine learning for algal biofuels: a critical review and perspective for the future

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