Myocardial ATP depletion detected noninvasively predicts sudden cardiac death risk in patients with heart failure
T. Jake Samuel, Shenghan Lai, Michael Schär, Katherine C. Wu, Angela M. Steinberg, An-Chi Wei, Mark E. Anderson, Gordon F. Tomaselli, Gary Gerstenblith, Paul A. Bottomley, Robert G. Weiss
T. Jake Samuel, Shenghan Lai, Michael Schär, Katherine C. Wu, Angela M. Steinberg, An-Chi Wei, Mark E. Anderson, Gordon F. Tomaselli, Gary Gerstenblith, Paul A. Bottomley, Robert G. Weiss
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Clinical Research and Public Health Cardiology

Myocardial ATP depletion detected noninvasively predicts sudden cardiac death risk in patients with heart failure

Abstract

BACKGROUND Sudden cardiac death (SCD) remains a worldwide public health problem in need of better noninvasive predictive tools. Current guidelines for primary preventive SCD therapies, such as implantable cardioverter defibrillators (ICDs), are based on left ventricular ejection fraction (LVEF), but these guidelines are imprecise: fewer than 5% of ICDs deliver lifesaving therapy per year. Impaired cardiac metabolism and ATP depletion cause arrhythmias in experimental models, but to our knowledge a link between arrhythmias and cardiac energetic abnormalities in people has not been explored, nor has the potential for metabolically predicting clinical SCD risk.METHODS We prospectively measured myocardial energy metabolism noninvasively with phosphorus magnetic resonance spectroscopy in patients with no history of significant arrhythmias prior to scheduled ICD implantation for primary prevention in the setting of reduced LVEF (≤35%).RESULTS By 2 different analyses, low myocardial ATP significantly predicted the composite of subsequent appropriate ICD firings for life-threatening arrhythmias and cardiac death over approximately 10 years. Life-threatening arrhythmia risk was approximately 3-fold higher in patients with low ATP and independent of established risk factors, including LVEF. In patients with normal ATP, rates of appropriate ICD firings were several-fold lower than reported rates of ICD complications and inappropriate firings.CONCLUSION To the best of our knowledge, these are the first data linking in vivo myocardial ATP depletion and subsequent significant arrhythmic events in people, suggesting an energetic component to clinical life-threatening ventricular arrhythmogenesis. The findings support investigation of metabolic strategies that limit ATP loss to treat or prevent life-threatening cardiac arrhythmias and herald noninvasive metabolic imaging as a complementary SCD risk stratification tool.TRIAL REGISTRATION ClinicalTrials.gov NCT00181233.FUNDING This work was supported by the DW Reynolds Foundation, the NIH (grants HL61912, HL056882, HL103812, HL132181, HL140034), and Russell H. Morgan and Clarence Doodeman endowments at Johns Hopkins.

Authors

T. Jake Samuel, Shenghan Lai, Michael Schär, Katherine C. Wu, Angela M. Steinberg, An-Chi Wei, Mark E. Anderson, Gordon F. Tomaselli, Gary Gerstenblith, Paul A. Bottomley, Robert G. Weiss

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Figure 3

Event-free survival based on cardiac ATP and LVEF.

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Event-free survival based on cardiac ATP and LVEF. Kaplan-Meier curves d...
Kaplan-Meier curves depicting the proportion of event-free survival across a median follow-up period of 10.7 years (range: 3.2–14.7 years) in individuals grouped by myocardial ATP (normal versus low ATP, <3.4 μmol/g) and by LVEF (low LVEF versus lower LVEF, <28% based on group median). The 2 subgroups with normal ATP (red lines) had the lowest arrhythmic risk, and the 2 subgroups with low ATP (black lines) had the highest risk, regardless of whether they had low ejection fraction (dotted lines) or lower ejection fraction (solid lines; log-rank, P = 0.024). The lowest arrhythmic risk subgroup had normal ATP and less depressed LVEF and exhibited nearly a 90% event-free survival at 10–15 years. The highest arrhythmic risk subgroup had both low ATP and the lowest LVEF, with a 5-year event-free survival of only approximately 35%. Low ATP, low ejection fraction n = 6; low ATP, lower ejection fraction n = 8; normal ATP, low ejection fraction n = 17; normal ATP, lower ejection fraction n = 15. The log-rank P value reflects the overall comparison of the 4 groups, and a significant P value rejects the null hypothesis that the groups are identical.