Introduction:
There is a need to implement a preclinical model in addition to the well established ischemic or volume-overload models that would mimic the clinical course of patients with chemotherapy-induced heart failure. Doxorubicin is an anthracycline chemotherapeutic that is widely used in oncology, although its cardiotoxicity.
Hypothesis:
Doxorubicin-induced left ventricular dysfunction in rats fulfills echocardiography and hemodynamic characteristics of chemotherapy-induced heart failure.
Methods:
We randomly assigned Ren-2 transgenic hypertensive (TGR, n = 17) and normotensive rats (HanSD, n = 22), at the age of 8 weeks to doxorubicin (2.5 mg/kg in 0.5 ml of normal saline) or placebo in 6 intraperitoneal doses within two weeks (cumulative doxorubicin dose 15 mg/kg). Two weeks later, we performed echocardiography study, pressure-volume analysis (PV), and we weighed the organs.
Results:
In doxorubicin groups, there was a decrease in the left ventricle weight (1,22 vs. 0,85 g in TGR), while an increase in wall stress (22036 vs. 29754 μL*mmHg/g in TGR). Echocardiography suggested heart remodeling with a decrease in relative wall thickness - RWT (1.02 vs. 0.65 mm in TGR), and together with PV analysis showed a decrease in systolic parameters - left ventricle ejection fraction - LVEF (71.41 vs. 59.96 % in TGR), end-systolic pressure-volume ratio - ESPVR (0.82 vs. 0.45 mmHg/uL in TGR) and preload recruitable stroke work - PRSW (75.71 vs. 60.98 mmHg in TGR). Ventricular-arterial coupling (VAC = Ea/Ees, a measure of cardiac efficiency) was worsened in the doxorubicin groups (1.69 vs. 2.52 in TGR). For all the above p < 0.05, in HanSD, the results were similar (all p < 0.05).
Conclusions:
Our results suggest that systolic dysfunction and decrease of cardiac efficiency in this model could be caused by heart atrophy, and such an animal model could potentially be an easily reproducible model of chemotherapy-induced heart failure in preclinical cardio-oncology studies.
Effect of reduced aortic compliance on cardiac efficiency and contractile function of in situ canine left ventricle.
