Mechanisms linking electrical alternans and clinical ventricular arrhythmia in human heart failure.

Mechanisms of ventricular tachycardia (VT) and ventricular fibrillation (VF) in patients with heart failure (HF) are undefined. The purpose of this study was to elucidate VT/VF mechanisms in HF by using a computational-clinical approach. In 53 patients with HF and 18 control patients, we established the relationship between low-amplitude action potential voltage alternans (APV-ALT) during ventricular pacing at near-resting heart rates and VT/VF on long-term follow-up. Mechanisms underlying the transition of APV-ALT to VT/VF, which cannot be ascertained in patients, were dissected with multiscale human ventricular models based on human electrophysiological and magnetic resonance imaging data (control and HF). For patients with APV-ALT k-score >1.7, complex action potential duration (APD) oscillations (≥2.3% of mean APD), rather than APD alternans, most accurately predicted VT/VF during long-term follow-up (+82%; -90% predictive values). In the failing human ventricular models, abnormal sarcoplasmic reticulum (SR) calcium handling caused APV-ALT (>1 mV) during pacing with a cycle length of 550 ms, which transitioned into large magnitude (>100 ms) discordant repolarization time alternans (RT-ALT) at faster rates. This initiated VT/VF (cycle length <400 ms) by steepening apicobasal repolarization (189 ms/mm) until unidirectional conduction block and reentry. Complex APD oscillations resulted from nonstationary discordant RT-ALT. Restoring SR calcium to control levels was antiarrhythmic by terminating electrical alternans. APV-ALT and complex APD oscillations at near-resting heart rates in patients with HF are linked to arrhythmogenic discordant RT-ALT. This may enable novel physiologically tailored, bioengineered indices to improve VT/VF risk stratification, where SR calcium handling and spatial apicobasal repolarization are potential therapeutic targets.

Bayer JD ，Lalani GG ，Vigmond EJ ，Narayan SM ，Trayanova NA ... -  《-》

Heart failure enhances susceptibility to arrhythmogenic cardiac alternans.

Wilson LD ，Jeyaraj D ，Wan X ，Hoeker GS ，Said TH ，Gittinger M ，Laurita KR ，Rosenbaum DS ... -  《-》

Rate-dependent action potential alternans in human heart failure implicates abnormal intracellular calcium handling.

Alternans in action potential voltage (APV-ALT) at heart rates <110 bpm is a novel index to predict ventricular arrhythmias. However, the rate dependency of APV-ALT and its mechanisms in failing versus nonfailing human myocardium are poorly understood. It is hypothesized that APV-ALT in human heart failure (HF) reflects abnormal calcium handling. Using a modeling and clinical approach, our objectives were to (1) determine how APV-ALT varies with pacing rate and (2) ascertain whether abnormalities in calcium handling explain the rate dependence of APV-ALT in HF. APV-ALT was analyzed at several cycle lengths (CLs) using a dynamic pacing protocol applied to a human left ventricle wedge model with various alterations in calcium handling. Modeled APV-ALT was used to predict APV-ALT in left ventricle monophasic action potentials recorded from HF (n = 3) and control (n = 2) patients with the same pacing protocol. Reducing the sarcoplasmic reticulum calcium uptake current < or =25%, the release current < or =11%, or the sarcolemmal L-type calcium channel current < or =43% of control predicted APV-ALT to arise at CL > or =600 ms and then increase in magnitude by >400% for CL <400 ms. In HF patients, APV-ALT arose at CL = 600 ms and then increased in magnitude by >500% at CL <350 ms. For all other model alterations and for control patients, APV-ALT occurred only at CL <500 ms. APV-ALT shows differing rate dependence in HF versus control patients, arising at slower rates in HF and predicted by models with abnormal calcium handling. Future studies should investigate whether APV-ALT at slow rates identifies patients with deranged calcium handing, including HF patients before decompensation or at risk for arrhythmias.

Bayer JD ，Narayan SM ，Lalani GG ，Trayanova NA ... -  《-》

Cardiomyocyte-Specific STIM1 (Stromal Interaction Molecule 1) Depletion in the Adult Heart Promotes the Development of Arrhythmogenic Discordant Alternans.

Cacheux M ，Strauss B ，Raad N ，Ilkan Z ，Hu J ，Benard L ，Feske S ，Hulot JS ，Akar FG ... -  《-》

Action potential dynamics explain arrhythmic vulnerability in human heart failure: a clinical and modeling study implicating abnormal calcium handling.

Narayan SM ，Bayer JD ，Lalani G ，Trayanova NA ... -  《-》