Journal article
Circulation: Arrhythmia and Electrophysiology, 2026
Dept. of Physiology / Center for Cardiometabolic Science / Envirome Institute
University of Louisville School of Medicine
Louisville, Kentucky
Dept. of Physiology / Center for Cardiometabolic Science / Envirome Institute
University of Louisville School of Medicine
Louisville, Kentucky
APA
Click to copy
Kucera, C., Ramalingam, A. R., Raph, S. M., Paily, R., Srivastava, S., Lorkiewicz, P., … Carll, A. (2026). Influence of Cooling Agents on the Arrhythmogenic and Autonomic Effects of Electronic Cigarettes in an In Vivo Model. Circulation: Arrhythmia and Electrophysiology.
Chicago/Turabian
Click to copy
Kucera, Cory, Anand R Ramalingam, Sean M. Raph, Romith Paily, Shweta Srivastava, Pawel Lorkiewicz, Aruni Bhatnagar, Matthew A. Nystoriak, and A. Carll. “Influence of Cooling Agents on the Arrhythmogenic and Autonomic Effects of Electronic Cigarettes in an In Vivo Model.” Circulation: Arrhythmia and Electrophysiology (2026).
MLA
Click to copy
Kucera, Cory, et al. “Influence of Cooling Agents on the Arrhythmogenic and Autonomic Effects of Electronic Cigarettes in an In Vivo Model.” Circulation: Arrhythmia and Electrophysiology, 2026.
BibTeX Click to copy
@article{cory2026a,
title = {Influence of Cooling Agents on the Arrhythmogenic and Autonomic Effects of Electronic Cigarettes in an In Vivo Model},
year = {2026},
journal = {Circulation: Arrhythmia and Electrophysiology},
author = {Kucera, Cory and Ramalingam, Anand R and Raph, Sean M. and Paily, Romith and Srivastava, Shweta and Lorkiewicz, Pawel and Bhatnagar, Aruni and Nystoriak, Matthew A. and Carll, A.}
}
Background Despite the growing popularity of electronic cigarettes, evidence is mounting that vaping induces autonomic nervous system imbalance, cardiac arrhythmia, and potentially even cardiac arrest. The ingredients menthol, WS-3, and WS-23 are cooling agents that enhance the appeal of e-cigarettes but bear unknown risks when inhaled. Methods: We systematically evaluated how these coolants influence the impacts of e-cigarettes on cardiac and cellular electrophysiology in mice and human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs), respectively. Mice were exposed by inhalation to e-cigarette aerosols generated from standard e-liquid solvents and 2.5% nicotine benzoate (vehicle), or from vehicle plus menthol, WS-3, or WS-23, at increasing concentrations throughout exposure. Telemetry-derived electrocardiograms were analyzed for changes in heart rate, heart rate variability (HRV), morphology, and ventricular premature beat arrhythmias (VPBs). hiPSC-CMs were evaluated for effects of serially increasing coolant concentrations on beat rate, electric field potential duration, and rate-corrected field potential duration from a newly validated formula, in the absence and presence of norepinephrine to simulate basal physiology and nicotine-evoked sympathoexcitation. Results: Upon e-cigarette aerosol inhalation, all coolants acutely enhanced vehicle-induced autonomic imbalance, but only the synthetic coolants, WS-3 and WS-23, potentiated ventricular arrhythmogenesis. VPBs during e-cigarette exposures correlated with sympathetic dominance and transient delays in ventricular repolarization measured by HRV and QTc, respectively; however, correlations were strongest for WS-23 despite no significant impact of coolants on nicotine intake. Conversely, in hiPSC-CMs, coolants did not affect basal physiology but slowed beat rate and shortened rate-corrected field potential duration during norepinephrine stimulation. Conclusions: Together, these data indicate that coolants dose-dependently enhance the arrhythmogenicity of e-cigarettes, likely through acute alterations in autonomic modulation and repolarization. Pending confirmation by human studies, these common non-nicotine additives may exacerbate e-cigarette cardiotoxicity and pose unique cardiovascular risks, particularly in those with arrhythmogenic susceptibility to sympathetic stimulation or slowed ventricular repolarization.