Methods to differentiate stem cells into cardiomyocytes have been well established. However, a limitation for the successful application of these cells for research and medicine has been their fetal-like phenotype with respect to cell size, contractility, calcium handling, metabolism, and electrophysiology. We sought to increase the maturity of human pluripotent stem cell derived cardiomyocytes (hPSC-CMs) through metabolic pathway regulation. We hypothesized that switching the main metabolic substrates from glucose to fatty acids, mimicking the switch from placental to breast milk nutrient consumption that occurs during development, will increase hPSC-CM maturation. RUES2 embryonic stem cells were differentiated into cardiomyocytes and then treated with base media with varying glucose and calcium concentrations and fatty acid supplementation. Using quantitative PCR to measure gene expression, we measured an inverse relationship between glucose levels and markers of cardiomyocyte maturation: increased expression of cardiac troponin I relative to skeletal troponin I isoforms (TNNI3:TNNI1), increased expression of metabolic (CPT1B, PPARGC1A) and electrical maturity markers (KCNJ2, RYR2). These maturation markers were not influenced with fatty acid supplementation but were enhanced upon the addition of thyroid hormone and dexamethasone. We further quantified nucleation and sarcomere spacing to assess structural features of maturation using confocal microscopy. To understand the mechanisms by which media nutrients and signaling molecules cause phenotypic changes we investigated the relationship between maturation and global epigenetic state. Western blot revealed increases in global acetylation levels, measured by histone H3 acetylation, linked to maturation signaling. These findings depict a direct relationship between glucose metabolism and the development of a mature phenotype in hPSC-CMs, mediated by epigenetic mechanisms.