Enhancing Cardiomyocyte Purity through Lactate-Based Metabolic Selection.

BACKGROUND: Direct reprogramming of fibroblasts into chemically induced cardiomyocyte-like cells (CiCMs) through small molecules presents a promising cell source for cardiac regeneration and therapeutic development. However, the contaminating non-cardiomyocytes, primarily unconverted fibroblasts, reduce the effectiveness of CiCMs in various applications. This study investigated a metabolic selection approach using lactate to enrich CiCMs by exploiting the unique metabolic capability of cardiomyocytes to utilize lactate as an alternative energy source. METHODS: Primary mouse embryonic fibroblasts (pMEFs) were reprogrammed into CiCMs and subjected to a glucose-depleted, lactate-supplemented medium for 4 days. Afterward, cell viability was analyzed, and cardiomyocyte efficiency was assessed through the expression of cardiac-specific markers. Additionally, electrophysiological function was evaluated by examining drug-induced responses. RESULTS: The lactate treatment led to a significant decrease in the viability of non-cardiomyocytes (pMEF-LAC), while CiCMs (CiCM-LAC) showed minimal cell death. Specifically, the expression of all cardiac-related markers was increased in CiCM-LAC. Metabolically purified CiCMs exhibited enhanced contractile force and increased contraction frequency compared to non-purified CiCMs, as well as an elevated responsiveness to drugs. CONCLUSION: This study demonstrates that lactate-based metabolic selection is an effective and practical approach for enriching CiCMs, offering a cost-effective alternative to other purification methods. The application of this strategy could potentially broaden the accessibility and utility of reprogrammed cardiomyocytes in cardiac regeneration and therapeutic development.