Living cells rely on enzymatic reaction networks (ERNs) to produce energy and building blocks to support cellular processes. Evolution has shaped these ERNs into interconnected sub-pathways to generate multiple outputs from multiple inputs, driving product formation across complex kinetic landscapes. Recently, significant progress has been made in reconstituting ERNs in vitro with the aim to produce value-added chemicals from sustainable substrates as an advanced biotechnology. However, most of these networks typically do not feature interconnected sub-pathways to simultaneously generate multiple outputs. Controlling such networks remains challenging due to the lack of sufficiently informative experimental datasets that can be utilized to train kinetic models which trace the dynamic properties of large ERNs and enable on-demand design.
In this project, we will develop an active learning-based pipeline in combination with microfluidic reactors, to obtain maximally informative datasets and fully map the kinetics of complex reaction networks