Heart-On-a-Chip with Integrated Ultrasoft Mechanosensors for Continuous Measurement of Cell- and Tissue-scale Contractile Stresses

Heart-on-a-chip platforms aim to miniaturize and replicate the complex structure and function of cardiac tissue. Traditionally, microfabricated pillar pairs have been employed in these systems to provide tissue anchorage and determine contractility parameters based on pillar deflection. However, this approach lacks the spatial resolution required to capture local cell- and tissue-scale mechanical stresses. In this study, we established a non-destructive optical method for continuous micro- and macro-scale contractile force measurements. We utilized our previously developed edge-labeled micro-spherical stress gauges (eMSGs) to map the stresses within a heart-on-a-chip. These ultrasoft mechanosensors visibly deform in response to stresses generated by cells and the extracellular matrix (ECM). The chip consisted of two cell-seeding chambers, each containing flexible silicone pillar pairs to support tissue formation and compaction. Neonatal rat cardiomyocytes (CMs) were encapsulated in a fibrin/Geltrex hydrogel mixture containing eMSGs and seeded into each chamber. Over time, the tissue compacted and began beating spontaneously, demonstrating structural alignment and functional cardiac hallmarks, such as calcium transients and tissue-scale beating. The effects of ECM composition on tissue function were examined, revealing that lower fibrin concentrations significantly enhanced contractile frequency, regularity, and stress generation. Local cell- and ECM-scale mechanics were further investigated by analyzing the shape changes of the dispersible sensors. Lateral and longitudinal stresses were calculated for each sensor, highlighting the critical role of tissue compaction and contraction in cell-generated forces. Finally, the platform was validated using two known drug candidates, with their effects on contractility clearly demonstrated.