Abstract P1145: Hydrogel Matrix Support Of Suspension-differentiated Hipscs Impacts Resulting In Vitro Cardiac Tissue Functionality

Abstract

Functional in vitro cardiac tissues are needed to provide insight into the cellular level of disease. Previously, we demonstrated hydrogel-encapsulated hiPSCs undergo cardiac differentiation and achieve cardiomyocyte (CM) maturation including T-tubule formation. To investigate the effect of encapsulation on differentiation and cardiac tissue functionality, here we compared PEG-fibrinogen (PF) microsphere (MS)-supported differentiation approach to self-aggregated embryoid body (EB) differentiation. Briefly, hiPSCs were encapsulated or formed into EBs; cardiac differentiation was initiated by Wnt activation and subsequent inhibition. CM content, contractile functionality, drug response, and electrophysiological properties were determined by flow cytometry, microscopy, and optical mapping, respectively.Initial diameter was 673±22 μm (coefficient of variance, COV=0.03) for MS and145±34 μm (COV=0.24) for EBs. The number of CMs produced (differentiation day 10) per initial hiPSC was significantly higher for MS (2.8 ± 1.8) than EBs (0.6±0.12). MS also yielded a higher percentage of CMs; MS-encapsulated hiPSC differentiation resulted in 74.7±13.8% CMs while for EBs it was 56±16.1 % (cTnT+, MF20+, n=14 and 5 batches, respectively, p<0.05). Myocardial contractility was also enhanced in cardiac MS as compared to EBs (similar CM content, day 10); maximum contraction velocity was four times higher for MS than EBs (139±17.5 μm/s versus 33.4±5.1 μm/s) and maximum relaxation velocity was fourteen times higher (97±7.2 μm/s versus 7.4±0.4 μm/s).Furthermore, cardiac MS responded more vigorously to isoproterenol (IP) and propranolol (P) (frequency +124% (IP), - 61% (P), versus +49% (IP) and -27%(P) for EB), suggesting that MS-CM β-adrenergic signaling may be more mature. Calcium transient propagation was more uniform in MS-CMs compared to EB-CMs; calcium transient duration (CTD) at 50% and 80% repolarization and calcium transient velocity were similar. In conclusion, MS supported cardiac differentiation supported higher CM content, faster contractility, and improved drug response in comparison to similarly differentiated EBs, demonstrating the potential of encapsulation to enhance cardiac tissue functionality for disease modeling.