Litcius/Paper detail

Automated loss of pulse detection on a consumer smartwatch

Kamal Shah, Anran Wang, Yiwen Chen, Jitender Munjal, Sumeet Chhabra, Anthony Stange, Enxun Wei, Thanh G. Phan, Tracy Giest, Beszel Hawkins, Dinesh Puppala, Elsina Silver, Lawrence Cai, Shruti Rajagopalan, Edward Shi, Yun-Ling Lee, Matt Wimmer, Pramod Rudrapatna, Thomas D. Rea, Shelten Yuen, Anupam Pathak, Shwetak Patel, Mark Malhotra, Marc Stogaitis, Jeanie Phan, Bakul Patel, Adam Vasquez, Christina Fox, Alistair Connell, Jim Taylor, Jacqueline Baras Shreibati, David P Miller, Daniel McDuff, Pushmeet Kohli, Tajinder Gadh, Jacob E. Sunshine

2025Nature34 citationsDOIOpen Access PDF

Abstract

Out-of-hospital cardiac arrest is a time-sensitive emergency that requires prompt identification and intervention: sudden, unwitnessed cardiac arrest is nearly unsurvivable 1–3 . A cardinal sign of cardiac arrest is sudden loss of pulse 4 . Automated biosensor detection of unwitnessed cardiac arrest, and dispatch of medical assistance, may improve survivability given the significant prognostic role of time 3,5 , but only if the false positive burden on public emergency medical systems is minimized 5–7 . Here we show that a multimodal, machine learning-based algorithm on a smartwatch can reach performance thresholds making it deployable at societal scale. First, using photoplethysmography (PPG), we show that wearable PPG measurements of peripheral pulselessness (induced via an arterial occlusion model) manifest similarly to pulselessness caused by a common cardiac arrest arrhythmia, ventricular fibrillation (VF). Based on the similarity of the PPG signal (from VF or arterial occlusion), we developed and validated a loss of pulse detection algorithm using data from peripheral pulselessness and free-living conditions. Once developed, we evaluated the end-to-end algorithm prospectively: there was 1 unintentional emergency call per 21.67 user-years across two prospective studies; the sensitivity was 67.23% (95% confidence interval, 64.32%–70.05%) in a prospective arterial occlusion cardiac arrest simulation model. These results suggest a new opportunity, deployable at scale, for wearable-based detection of sudden loss of pulse while minimizing societal costs of excess false detections 7 .

Topics & Concepts

SmartwatchPulse (music)Computer scienceWearable computerEmbedded systemTelecommunicationsDetectorPower Line Communications and NoiseBluetooth and Wireless Communication TechnologiesIoT-based Smart Home Systems