Monitoring Cardiac Activity by Detecting Subtle Head Movements Using MEMS Technology

2022 IEEE International Symposium on Inertial Sensors and Systems (INERTIAL) Pub Date : 2022-05-08 DOI:10.1109/INERTIAL53425.2022.9787725

S. Solbiati, A. Buffoli, V. Megale, G. Damato, B. Lenzi, G. Langfelder, E. Caiani

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Abstract

Ballistocardiography (BCG) is a non-invasive technique that measures the recoil forces of the body in reaction to the cardiac contraction and blood flow through the vessels. This work compares the performance of a virtual reality (VR) headset-embedded gyroscope and of a novel high-performance gyroscope in measuring median HR from the BCG signal obtained from subtle head movements. Nine healthy volunteers were enrolled in this study. Head BCG signals were acquired for 1 minute in supine position using the triaxial gyroscope (VRG) embedded in an Oculus Quest (Facebook) headset, and a monoaxial high-performance gyroscope (HPG). 1-lead ECG signal was acquired simultaneously and used as a gold standard for HR measurement (HRECG). Automatic beat-by-beat identification was performed on the BCG signals, from which median HR was computed (HRVRG and HRHPG). Results obtained with the three sensors were statistically compared, and linear regression and Bland Altman analyses were performed. Pitch and roll head rotations provided more accurate HR estimates compared to the yaw rotation, with more marked peaks in the BCG signal, possibly due to the to the anatomical orientation of the carotid arteries and to how the head is perfused with blood. Also, the HPG outperformed the VRG, thus potentially allowing a more detailed analysis of the BCG signal morphology, with possible application in the extraction of novel biomarkers with clinical utility.

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利用MEMS技术检测头部细微运动来监测心脏活动

弹道心动图(BCG)是一种非侵入性技术，测量身体对心脏收缩和血管血流的反应。这项工作比较了虚拟现实(VR)头戴式陀螺仪和一种新型高性能陀螺仪在测量从头部细微运动获得的BCG信号中值HR方面的性能。9名健康志愿者参加了这项研究。使用嵌入Oculus Quest (Facebook)头戴式耳机的三轴陀螺仪(VRG)和单轴高性能陀螺仪(HPG)在仰卧位获取头部BCG信号1分钟。同时采集1导联心电信号，作为心率测量(HRECG)金标准。对BCG信号进行自动逐拍识别，从中计算中位心率(HRVRG和HRHPG)。对三种传感器得到的结果进行统计比较，并进行线性回归和Bland Altman分析。与偏航旋转相比，俯仰和侧滚头部旋转提供了更准确的HR估计，在BCG信号中有更明显的峰值，可能是由于颈动脉的解剖方向和头部的血液灌注方式。此外，HPG优于VRG，因此有可能对BCG信号形态进行更详细的分析，并可能应用于提取具有临床实用性的新型生物标志物。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 IEEE International Symposium on Inertial Sensors and Systems (INERTIAL)

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