Abstract 15136: Matrix Mechanics Regulate Engineered Myocardial Microtissue Organization and Contractility

Introduction: The mechanical function of the myocardium is dictated by cardiomyocytes (CMs) and the surrounding fibrous extracellular matrix (ECM). Due to limitations in existing approaches for engineering myocardial tissue, how CMs sense and respond to mechanical microenvironmental changes remains understudied. Here, we established a method for creating arrays of cardiac microtissues with highly tunable mechanical features by integrating synthetic, fibrous matrices and iPSC-CMs. Through real-time contractility readouts enabled, we explored how biomechanical cues influence engineered cardiac tissue assembly and function. Methods: Arrayed cardiac microtissues were generated by selectively photo-crosslinking electrospun dextran vinyl sulfone fiber matrices onto pairs of microfabricated PDMS cantilevers. Subsequently, iPSC-CMs were patterned onto matrices using a microfabricated seeding mask. Matrix and cantilever stiffnesses were tuned by adjusting photoinitiator concentrations and cantilever geometry, respectively. Results: In tissues contracting against soft cantilevers (0.41 N/m), tissue contractile stress decreased with increasing matrix stiffness (E = 0.68 to 17.3 kPa). We also observed an increase in contractile stress on soft and aligned matrices, compared to non-aligned matrices. However, tissues contracting against stiffer cantilevers (1.2 N/m) exerted similar contractile stresses independent of matrix alignment. This may be explained by the enhanced alignment of myofibrils in non-aligned matrices contracting against stiffer posts. The size of vinculin-rich cell-ECM adhesion decreased on stiff matrices. Vinculin also localized to z-discs forming organized costameres on soft matrices. Tissue response to mavacamten suggests that β-cardiac myosins are required for costamere formation and myofibril maturation. Conclusions: We developed a new microfabrication strategy to create tunable cardiac microtissues and examined how biomechanical cues affect tissue assembly and function. We found that matrix stiffness, matrix alignment, and tissue constraint distinctly affect iPSC-CM function and structure, potentially due to differential influences on costamere formation and myofibrillar assembly.