Since the advent of the generation of human induced pluripotent stem cells (hiPSCs), numerous protocols have been developed to differentiate hiPSCs into cardiomyocytes and then subsequently assess their ability to recapitulate the properties of adult human cardiomyocytes. However, hiPSC-derived cardiomyocytes (hiPSC-CMs) are often assessed in single-cell assays. A shortcoming of these assays is the limited ability to characterize the physiological parameters of cardiomyocytes, such as contractile force, due to random orientations. This protocol describes the differentiation of cardiomyocytes from hiPSCs, which occurs within 14 d. After casting, cardiomyocytes undergo 3D assembly. This produces fibrin-based engineered heart tissues (EHTs)-in a strip format-that generate force under auxotonic stretch conditions. 10-15 d after casting, the EHTs can be used for contractility measurements. This protocol describes parallel expansion of hiPSCs; standardized generation of defined embryoid bodies, growth factor and small-molecule-based cardiac differentiation; and standardized generation of EHTs. To carry out the protocol, experience in advanced cell culture techniques is required.
Background: Human engineered heart tissue (EHT) transplantation represents a potential regenerative strategy for heart failure patients and has been successful in preclinical models. Clinical application requires upscaling, adaptation to good manufacturing practices (GMP) and determination of the effective dose. Methods: Cardiomyocytes were differentiated from three different human induced pluripotent stem cell (hiPSC) lines including one reprogrammed under GMP conditions. Protocols for hiPSC expansion, cardiomyocyte differentiation and EHT generation were adapted to substances available in GMP quality. EHT geometry was modified to generate patches suitable for transplantation in a small animal model and perspectively humans. Repair efficacy was evaluated at 3 doses in a cryo-injury guinea pig model. Human-scale patches were epicardially transplanted onto healthy hearts in pigs to assess technical feasibility. Results: We created mesh structured tissue patches for transplantation in guinea pigs (1.5x2.5 cm, 9-15x10 6 cardiomyocytes) and pigs (5x7 cm, 450 x10 6 cardiomyocytes). EHT patches coherently beat in culture and developed high force (mean 4.6 mN). Cardiomyocytes matured, aligned along the force lines, and demonstrated advanced sarcomeric structure and action potential characteristics closely resembling human ventricular tissue. EHT patches containing ~4.5, 8.5, 12x10 6 or no cells were transplanted 7 days after cryo-injury (n=18-19 per group). EHT transplantation resulted in a dose-dependent remuscularization (graft size: 0-12% of the scar). Only high-dose patches improved left-ventricular function (+8% absolute, +24% relative increase). The grafts showed time-dependent cardiomyocyte proliferation. While standard EHT patches did not withstand transplantation in pigs, the human-scale patch enabled successful patch transplantation. Conclusions: EHT patch transplantation resulted in a partial remuscularization of the injured heart and improved left-ventricular function in a dose-dependent manner in a guinea pig injury model. Human scale patches were successfully transplanted in pigs in a proof-of-principle study.
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