LAUSR

Introduction: Sudden cardiac death (SCD) is the leading cause of death in USA. Heart failure (HF) confers high SCD risk, but most SCD victims do not have HF or well-defined genetic abnormalities. The underlying mechanisms are poorly understood, precluding the design of more effective strategies for risk stratification and therapy. We previously showed that distinct non-linear patterns of cardiac repolarization strongly and independently predict SCD in HF patients [PMID: 27044982]. We also showed in a unique guinea pig HF model that increased levels of mitochondrial reactive oxygen species (mROS) drive spontaneous SCD, even before HF onset [PMID: 29898892]. Herein, we further dissect the underlying mechanisms. Hypothesis: Increased mROS levels in pressure overloaded hearts reduce K+ currents, destabilize the resting membrane potential, increase repolarization lability and cause SCD. Methods: Guinea pigs were randomized to Sham, aortic banding (AC), or AC with daily brief low-dose β-adrenergic stress (ACi) with and without in vivo mROS scavenger MitoTEMPO (ACi+MT). We performed time series analyses on recordings of: (1) 24-hour ECG QT interval in freely ambulating animals before sacrifice at 4 weeks; (2) pressure-volume and electrophysiology (EP) in excised perfused hearts; and (3) duration of action potential (APd), calcium transient (CaTd) and sarcomere shortening (SSd) in isolated LV myocytes. Results: About 50% of ACi animals had SCD by 4 weeks. Increased QT entropy in ACi (at 1 week) predicted SCD over followup, similar to HF patients. Compared to Sham and ACi+MT, LV myocytes isolated from AC and ACi had reduced inward (IK1) and delayed slow (IKs) and rapid (IKr) rectifier currents; and increased beat-to-beat lability in APd, CaTd and SSd. The late Na and L-type Ca currents were similar between models. Acute exposure to isoproterenol (Iso) and carbachol (CCh) increased lability in LV myocytes compared to Iso or CCh alone. Conclusions: High mROS levels reduce repolarization reserve in LV myocytes and contribute, at least in part, to the non-linear dynamics of ventricular repolarization (reflected by high QT entropy), leading to spontaneous arrhythmic SCD. These findings provide important new mechanistic insight with direct clinical implications.