Integration of cardiac energetics, function and histology from isolated rat hearts perfused with doxorubicin and doxorubicin-ol; a model for use in drug safety evaluations.

The isolated rat heart (Langendorff) assay combined with NMR spectroscopy and histology were used to elucidate functional, metabolic, and histological signs of cardiotoxicity resulting from acute exposure to clinically relevant concentrations of doxorubicin and its metabolite dox-ol. Doxorubicin blood concentrations and pharmacokinetic parameters were assessed following a clinically relevant dose of 2 mg/kg in order to select concentrations for isolated heart perfusions. Isolated rat hearts were exposed to 1 or 10 µM of doxorubicin or 0.3 µM dox-ol for at least 60 min using the Langendorff perfusion method. Effects on heart function were monitored using ECGs, left ventricular contraction parameters, and microscopic histology. Cardiac energetics (PCr, ATP, and Pi) were evaluated before, during, and after exposure to doxorubicin/dox-ol in perfused hearts using NMR spectroscopy. Cardiac effects were evident following clinically relevant concentrations of doxorubicin and dox-ol in isolated rat hearts demonstrated by altered heart function, energetic reserve, and microscopic lesions. A cardiac stress test utilizing isoproterenol resulted in enhanced functional response and reductions in PCr in doxorubicin versus vehicle treated hearts indicating possible alterations in the isoproterenol mediated pathway. Dox-ol treated hearts were similar to control with regard to function, but exhibited histologic findings. The use of combined Langendorff/NMR/histology methodologies allowed for comparison of multiple indices of cardiac function at one time in which cardiac effects were evident in multiple parameters. SHORT ABSTRACT: The isolated rat heart assay combined with NMR spectroscopy and histology was used to elucidate functional, metabolic, and histological signs of cardiotoxicity resulting from acute exposure to clinically relevant concentrations of doxorubicin and its metabolite dox-ol. Heart function was altered and microscopic signs of toxicity were evident with dox and dox-ol exposures. The use of combined Langendorff/NMR/histology assays allowed for comparison of multiple indices of cardiac function at one time in which cardiac effects were evident in multiple parameters.

Effects of tyrosine kinase inhibitors on rat isolated heart function and protein biomarkers indicative of toxicity.

INTRODUCTION: Cardiac toxicity, manifested as diminished contractility, ischemic heart disease, and heart failure is a major issue in drug safety. Concerns revolve around targeted drugs (TKIs) where contractility effects were not anticipated. The ability to predict cardiac toxicity early would help to de-risk drugs in development and prepare physicians to manage risk in the clinic. Issues with current preclinical studies include insufficient testing with informative, translatable models, and predictive biomarkers. The isolated heart model is amenable to multiple assessments which can be combined with current technologies to assess toxicity on a multi-scale level. METHODS: Rat isolated heart model was used to assess changes in left ventricular (LV) contractility and protein biomarkers BNP, IL6, TNFα, and cardiac troponins T (TnT) and I (TnI). Responses were assessed during perfusion with modified Henseleit Krebs (MHK), and 20 min concentration escalations of verapamil, carbonyl cyanide 4-(trifluoromethoxy)phenylhydrazone (FCCP), isoproterenol, or 20 min escalations bracketing clinical blood concentrations of sunitinib, sorafenib, and erlotinib. LV parameters and effluent for biomarkers were collected before and during escalating drug concentrations. RESULTS: Verapamil reduced inotropy with no change in biomarkers, FCCP and isoproterenol reduced and increased heart function respectively and increased TnT and TNFα. Erlotinib had no significant effects on function or biomarkers. Sunitinib diminished function, increased TNFα at 0.1 µM, and increased TnT at higher concentrations. Sorafenib dose dependently increased TNFα beginning at 0.1 µM, reducing contractility and flow rate at 0.6 µM. DISCUSSION: The ex-vivo assay is a sensitive and predictive model for assessing changes in heart function and biomarkers of toxicity and injury. This assay demonstrates the potential for sunitinib and sorafenib to cause cardiac toxicity in humans. Also, TNFα appears to be a biomarker in the heart prior to injury. Due to its versatility, the isolated heart assay has potential to fill gaps in cardiac safety testing early in drug development.