Litcius/Paper detail

Respiratory analysis during sleep using a chest-worn accelerometer: A machine learning approach

Franziska Ryser, Simon Hanassab, Olivier Lambercy, Esther Werth, Roger Gassert

2022Biomedical Signal Processing and Control28 citationsDOIOpen Access PDF

Abstract

There is a great interest in observing breathing patterns during sleep, as sleep disturbances can be caused by respiratory irregularity and cessations. In this paper, we introduce the first steps to an accelerometer-based screening tool for respiratory rate estimation and a novel approach towards detecting breathing cessations such as apnea/hypopnea, by extending and combining established signal processing routines with machine learning. From a single chest-worn accelerometer, we estimate the respiratory rate based on the inhalation/exhalation movements of the chest and carry out a full overnight validation. On this basis, we build a set of features customized to detect irregular respiratory activity, including a novel feature: the respiratory peak variance (RPV). From thirteen healthy subjects, a classification model was trained, validated, and tested with over 98 h of PSG-labeled accelerometer data. The algorithm estimated the respiratory rate with a mean difference of 1.8 breaths per minute compared to respiratory inductance plethysmography during overnight PSGs. The machine learning classifier detected respiratory cessations with a sensitivity and specificity of 76.05% and 70.05% respectively, with an overall accuracy of 70.95%. We successfully demonstrated the potential of a novel respiratory feature set in a preliminary application with young healthy volunteers for respiratory rate estimation and in identifying apnea/hypopnea events during overnight sleep. We present a simple and unobtrusive wearable system that can serve as a home screening tool for sleep-related breathing disorders. • Chest-worn accelerometer to monitor respiration during sleep. • Validation of respiratory rate estimation in extensive overnight sleep. • Novel feature set for accelerometer data customized to identify breathing. • Machine learning model to discriminate between regular and disrupted breathing.

Topics & Concepts

AccelerometerSleep (system call)Computer scienceRespiratory systemPhysical medicine and rehabilitationArtificial intelligenceMedicineMachine learningSimulationInternal medicineOperating systemObstructive Sleep Apnea ResearchNon-Invasive Vital Sign MonitoringContext-Aware Activity Recognition Systems