Inversion and computational maturation of drug response using human stem cell derived cardiomyocytes in microphysiological systems.

Our research represents the intersection of two technologies, advanced hiPSC organ-on-chip systems and computation modeling of excitable cells, in order to leverage both to improve understanding and prediction of drug induced cardiac events. hiPSCs represent a powerful new tool for in vitro research, however, a principal challenge for their application is the relative immaturity of the hiPSC-derived cells compared to their in vivo counterparts. This is particularly difficult in the case of cardiomyocytes, since these cells develop and mature over decades in the body, rendering lab reproduction impractical. In this manuscript, we suggest a novel remedy for this problem - the mapping of data collected using immature hiPSC-derived cardiomyocytes directly onto developed mathematical models of mature cells. We demonstrate that changes to optically measured transmembrane potentials and calcium dynamics from ion channel blocking drugs in hiPSC-derived cardiomyocytes can be effectively inverted, and this inversion can be used to estimate how the drug would behave in adult cardiomyocytes. In this way, we provide a new framework for leveraging the human specificity of hiPSCs to detect unwanted cardiac side effects of new compounds, a practical problem of immense importance in drug development.