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Deep reinforcement learning for the control of microbial co-cultures in bioreactors

Neythen J. Treloar, Alex J. H. Fedorec, Brian Ingalls, C. Barnes

2020PLoS Computational Biology127 citationsDOIOpen Access PDF

Abstract

Multi-species microbial communities are widespread in natural ecosystems. When employed for biomanufacturing, engineered synthetic communities have shown increased productivity in comparison with monocultures and allow for the reduction of metabolic load by compartmentalising bioprocesses between multiple sub-populations. Despite these benefits, co-cultures are rarely used in practice because control over the constituent species of an assembled community has proven challenging. Here we demonstrate, in silico, the efficacy of an approach from artificial intelligence-reinforcement learning-for the control of co-cultures within continuous bioreactors. We confirm that feedback via a trained reinforcement learning agent can be used to maintain populations at target levels, and that model-free performance with bang-bang control can outperform a traditional proportional integral controller with continuous control, when faced with infrequent sampling. Further, we demonstrate that a satisfactory control policy can be learned in one twenty-four hour experiment by running five bioreactors in parallel. Finally, we show that reinforcement learning can directly optimise the output of a co-culture bioprocess. Overall, reinforcement learning is a promising technique for the control of microbial communities.

Topics & Concepts

BioreactorReinforcement learningReinforcementBiologyBiochemical engineeringMicrobiologyArtificial intelligenceComputer scienceEngineeringBotanyStructural engineeringInnovative Microfluidic and Catalytic Techniques Innovation3D Printing in Biomedical ResearchViral Infectious Diseases and Gene Expression in Insects
Deep reinforcement learning for the control of microbial co-cultures in bioreactors | Litcius