Cardiomyocyte Mechanics In Animal Models Of Heart Failure With Preserved Ejection Fraction

Heart failure with preserved ejection fraction (HFpEF) has few effective therapies yet exacts substantial mortality. Its multi-system nature has made animal modeling difficult, but recent efforts combining diet-induced obesity and hemodynamic stress are popular: mouse - L-NAME/high-fat diet (HFD) and ovariectomized (OVX) females with HFD-induced obesity/cardiac pressure overload (PO) (HFD+OVX+PO), ZSF1 rat, and obese/hypertensive Göttingen minipigs. We reported human HFpEF myocyte defects including reduced Ca 2+ -activated maximum tension (T max ) negatively correlate with body mass index, reduced Hill coefficient (n H, e.g., cooperativity) and Ca 2+ at 50% T max (EC 50 ), and higher resting tension. Here we tested whether such deficits are found in HFpEF animal models. The L-NAME/HFD mouse had no differences in Ca 2+ -activated (p=0.20) or resting (p=0.75) tension. In obese ZSF-1 rats, while T max (p=0.23) and resting tension (p=0.39) were not different, n H was reduced (2±1 vs. 4±2 p=0.01). In HFD+OVX+PO mice, T max (15±2 vs. 20±2 mN/mm 2 , p=0.006) and EC 50 (1.9±0.6 vs. 2.4±0.7 μM, p=0.008) were reduced, but resting tension (p=0.70) was not different. In the Göttingen minipig HFpEF model, EC 50 (p=0.93) and n H (p=0.35) were not different, whereas T max was reduced (17±3 vs. 27±3 mN/mm 2 , p=2x10 -6 ) and tension less at physiologic Ca 2+ . Resting tension was lower (not greater) in this model (p=0.001). The HFD+OVX+PO and minipig HFpEF models recapitulate depressed Ca 2+ -activated tension as in obese human HFpEF, whereas none manifested increased resting tension ( Table 1 ). Studies investigating HFpEF sarcomere dysfunction should consider these findings in model selection.