Step experiments enable efficient exploration of microbial microaerobic steady states
- Lena Kranert,
- Johannes Pohlodek,
- Stefanie Duvigneau,
- Alexander Rose,
- Lisa Carius,
- Achim Kienle,
- Rolf Findeisen
Johannes Pohlodek
Control and Cyber-Physical Systems Laboratory, Technical University of Darmstadt
Stefanie Duvigneau
Institute for Automation Engineering, Otto von Guericke University Magdeburg
Alexander Rose
Control and Cyber-Physical Systems Laboratory, Technical University of Darmstadt
Lisa Carius
Institute for Automation Engineering, Otto von Guericke University Magdeburg
Achim Kienle
Institute for Automation Engineering, Otto von Guericke University Magdeburg, Process Synthesis and Process Dynamics, Max Planck Institute for Dynamics of Complex Technical Systems Magdeburg
Rolf Findeisen
Control and Cyber-Physical Systems Laboratory, Technical University of Darmstadt
Abstract
Microbial processes are widely considered an alternative to classical chemical processes. However, the need for expensive nutrients often increases the costs of those processes. Microaerobic conditions increase the productivity of microbial processes without requiring expensive feeds. The literature describes several techniques to perform microaerobic experiments, but they are often limited to a single condition per experiment. We introduce step experiments to explore the microaerobic range of two different organisms. For this, we present two different strategies to adjust microaerobic conditions and validate them for two experimental setups: the microaerobic ethanol production using Escherichia coli grown on glycerol and the oxygen-limited polyhydroxybutyrate production of Cupriavidus necator using fructose. This work shows, for the first time, that Cupriavidus necator can produce polyhydroxybutyrate under heterotrophic, oxygen-limited conditions. We consider the proposed step-wise exploration a useful tool to perform microaerobic experiments in a more cost-and time-efficient way.