Embryonic Stem Cell‐Based Cardiopatches Improve Cardiac Function in Infarcted Rats

Pluripotent stem cell‐seeded cardiopatches hold promise for in situ regeneration of infarcted hearts. Here, we describe a novel cardiopatch based on bone morphogenetic protein 2‐primed cardiac‐committed mouse embryonic stem cells, embedded into biodegradable fibrin matrices and engrafted onto infarcted rat hearts. For in vivo tracking of the engrafted cardiac‐committed cells, superparamagnetic iron oxide nanoparticles were magnetofected into the cells, thus enabling detection and functional evaluation by high‐resolution magnetic resonance imaging. Six weeks after transplantation into infarcted rat hearts, both local ( p < .04) and global ( p < .015) heart function, as well as the left ventricular dilation ( p < .0011), were significantly improved ( p < .001) as compared with hearts receiving cardiopatches loaded with iron nanoparticles alone. Histological analysis revealed that the fibrin scaffolds had degraded over time and clusters of myocyte enhancer factor 2‐positive cardiac‐committed cells had colonized most of the infarcted myocardium, including the fibrotic area. De novo CD31‐positive blood vessels were formed in the vicinity of the transplanted cardiopatch. Altogether, our data provide evidence that stem cell‐based cardiopatches represent a promising therapeutic strategy to achieve efficient cell implantation and improved global and regional cardiac function after myocardial infarction.