Modeling doxorubicin-induced cardiotoxicity with human myocardial tissue slices: insights on genetic susceptibility and cardioprotection

Abstract

Abstract Funding Acknowledgements Type of funding sources: Public grant(s) – National budget only. Main funding source(s): PSIDER and HARVEY (ZonMW) Introduction Cardiotoxicity poses a significant challenge in drug development, often leading to the withdrawal of approved drugs. To address this issue, there is a critical need for improved models to predict cardiac adverse effects. In line with the imperative for animal-free preclinical testing, this study aimed to develop a novel model using human myocardial tissue slices to get a deeper understanding and potential prevention of doxorubicin-Induced cardiotoxicity. Methods Human myocardial tissue slices of 300 μm thick were derived from end-stage heart failure patients explanted hearts, including those harbouring likely or pathogenic cardiovascular mutations (class 4 and 5) (N=3) and non-genetic cardiovascular etiology (N=3). Myocardial tissue slices were cultured under physiological mechanical and electrical conditions. Slices were exposed to doxorubicin (1 µM) over a 10-day culture period, and their responses were compared to DMSO-vehicle controls, by recording contractile force and Ca2+ transients. Additionally, a subset of slices was treated with a cardioprotective agent, dexrazoxane (100 µM), 1 day prior to and during doxorubicin exposure to assess potential cardioprotection. Results Doxorubicin-exposed slices with a pathogenic mutation exhibited reduced mechanical force, increased threshold potential, and impaired ability to follow pacing at higher frequencies. Additionally, aberrations in calcium handling, manifested as arrhythmia-like disconnection of muscle fibers, were notably observed in these slices. Instead, slices from patients without pathogenic mutations showed minimal cardiotoxicity when exposed to doxorubicin. Encouragingly, pretreatment with dexrazoxane demonstrated a protective effect against doxorubicin-induced cardiotoxicity in the genetically susceptible group. Our functional findings corroborated our structural data, highlighting the breakdown of sarcomere structure and cell-cell connections and increased DNA damage, particularly in patients harbouring a genetic cardiovascular mutation. Conclusion In summary, human myocardial tissue slices faithfully recapitulate doxorubicin-induced cardiotoxicity. Importantly, our data suggests the utility of employing genetic testing for known cardiovascular mutations as a valuable step before initiating doxorubicin treatment. Additionally, we demonstrate for the first time the in vitro cardioprotective potential of dexrazoxane in a human tissue model. These findings pave the way for using ex vivo myocardial tissue slices to evaluate cardiotoxicity and their value as a powerful tool for evaluating the efficacy and delivery approaches.