Abstract Body: Oxytocin (OT) is a peptide made in the hypothalamus and released into circulation by the pituitary gland. Known for its role in childbirth and lactation, recent research suggests that OT has significant cardiovascular benefits, reducing the risk of cardiovascular diseases such as hypertension and atherosclerosis. We tested if OT has beneficial effects on cardiovascular function in a rat model of pressure overload heart failure (HF). Neonatal Sprague Dawley rats underwent transaortic constriction (TAC). Pressure overload and cardiac dysfunction progressed as animals matured. Echocardiography at 5 weeks of age confirmed reduced ejection fraction. Animals were then randomly assigned to receive daily IP injections of either OT (treatment) or saline (control) for two weeks. Echocardiography was performed again before hearts were excised for optical mapping studies to test for electrophysiological differences between groups. Hearts were electromechanically uncoupled using blebbistatin and transmembrane potential (RH237) and intracellular Ca2+ (Rhod2am) were simultaneously mapped during a dynamic restitution protocol. Preliminary results indicate that rats in the treatment (OT, n=3) group had improved cardiac function compared to controls (saline, n=3), with higher ejection fraction (66.71 ± 9.44 vs. 25.83 ± 17.93, p=0.0125), higher cardiac output (62.4 ± 11.45 vs. 20.35 ± 6.12, p=0.0025), and greater stroke volume (180.2 ± 18.19 vs. 73.96 ± 37.29, p=0.0057). Preliminary optical mapping results indicate that the hearts of OT-treated rats (n=3) have lower steady state action potential duration (APD) compared to controls (n=2). APD60 decreased from 109.5 ± 10.09 to 75.79 ± 21.94 (p=.0725) and APD80 decreased from 133.1 ± 10.22 to 101.1 ± 24.5 (p=.09595), indicating preservation of repolarizing currents corresponding to healthier electrophysiological function. In summary, our preliminary results suggest exogenous IP OT administration could have a potent cardioprotective effect on chronic and severe pressure overload hearts. Future work will investigate potential mechanisms of OT mediated cardio-protection, including sites of action.