Overnight Sleep Staging Using Chest-Worn Accelerometry
Author:
Schipper Fons12ORCID, Grassi Angela2ORCID, Ross Marco13ORCID, Cerny Andreas4ORCID, Anderer Peter3ORCID, Hermans Lieke1ORCID, van Meulen Fokke15ORCID, Leentjens Mickey6ORCID, Schoustra Emily6ORCID, Bosschieter Pien15ORCID, van Sloun Ruud J. G.1ORCID, Overeem Sebastiaan15ORCID, Fonseca Pedro12ORCID
Affiliation:
1. Department of Electrical Engineering, Eindhoven University of Technology, 5612 AP Eindhoven, The Netherlands 2. Philips Sleep and Respiratory Care, 5656 AE Eindhoven, The Netherlands 3. The Siesta Group, 1210 Vienna, Austria 4. FH Technikum Wien, 1200 Wien, Austria 5. Center for Sleep Medicine Kempenhaeghe, 5591 VE Heeze, The Netherlands 6. Department of Otorhinolaryngology, Head and Neck Surgery OLVG West, 1061 AE Amsterdam, The Netherlands
Abstract
Overnight sleep staging is an important part of the diagnosis of various sleep disorders. Polysomnography is the gold standard for sleep staging, but less-obtrusive sensing modalities are of emerging interest. Here, we developed and validated an algorithm to perform “proxy” sleep staging using cardiac and respiratory signals derived from a chest-worn accelerometer. We collected data in two sleep centers, using a chest-worn accelerometer in combination with full PSG. A total of 323 participants were analyzed, aged 13–83 years, with BMI 18–47 kg/m2. We derived cardiac and respiratory features from the accelerometer and then applied a previously developed method for automatic cardio-respiratory sleep staging. We compared the estimated sleep stages against those derived from PSG and determined performance. Epoch-by-epoch agreement with four-class scoring (Wake, REM, N1+N2, N3) reached a Cohen’s kappa coefficient of agreement of 0.68 and an accuracy of 80.8%. For Wake vs. Sleep classification, an accuracy of 93.3% was obtained, with a sensitivity of 78.7% and a specificity of 96.6%. We showed that cardiorespiratory signals obtained from a chest-worn accelerometer can be used to estimate sleep stages among a population that is diverse in age, BMI, and prevalence of sleep disorders. This opens up the path towards various clinical applications in sleep medicine.
Funder
Eindhoven MedTech Innovation Center
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