Heart disease is a major health pandemic, and the myocardial infarction (MI), also known as a heart attack, is the leading cause of death. This is because adult cardiomyocytes (CMs) present in the heart cannot divide and proliferate, preventing the heart from regenerating itself and repairing tissue damage. From developmental studies in rodents, we know the Notch signaling pathway is crucial in mediating expansion and proliferation of CMs during development, as impairments in Notch lead to cardiac defects. Notch is inactive in adult CMs, which suggests it plays a role in CM renewal; however, this mechanism is still unknown. Thus, our goal is to investigate the role of Notch in CM proliferation and cell cycle regulation. For the purpose of this study, we are using CMs differentiated from a human embryonic stem cell line, RUES2. Differentiation was completed over a 17-day period by culturing the cells as a monolayer. On Day 0, Chiron 99021 is added to activate Wnt signaling, promoting mesoderm formation. Wnt-C59 is added at Day 2 to inhibit Wnt signaling and differentiate the cells into progenitors, and B27 supplement at Day 6 promotes full differentiation into CMs. This adherent protocol recapitulates every step of natural heart development in vitro. Purity of the cell populations, as assessed by flow cytometry staining for cardiac troponin T (cTnT), was 97.1 ± 0.9% cTnT+. We then determined the proliferative capabilities of CMs in the presence of a Notch inhibitor, DAPT. DAPT inhibits gamma-secretase, a transmembrane protein that normally proteolytically cleaves Notch during signaling, thus inactivating the Notch pathway. Treatment with DAPT significantly decreased cell proliferation by about 50%, confirming that Notch directly affects CM proliferation. The results of this study increase our knowledge of CM physiology and the mechanisms behind cell cycle withdrawal, and provide new insights into improving CM renewal.