Enabling Complex Impedance Spectroscopy for Cardio-Respiratory Monitoring with Wearable Biosensors: A Case Study

R. Mathews, E. Jovanov
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Abstract

Recent advances in commercially available integrated complex impedance spectroscopy controllers have brought rapid increases in the quality of systems available to researchers for wearable and remote patient monitoring applications. As a result, novel sensing methods and electrode configurations are increasingly viable, particularly for low-power embedded sensors and controllers for general electrochemical analysis. This study evaluates a case study of the four electrode locations suitable for wearable monitoring of respiratory and heart activity monitoring using complex impedance spectroscopy. We use tetrapolar electrode configurations with ten stimulation frequencies to characterize the relative differences in measurement sensitivity. Measurements are performed and compared for the magnitude, phase, resistive, and reactive components of the bioimpedance using two COTS-based controllers, the TI AFE4300 and MAX30009. We identify the highest percent relative changes in the magnitude of the impedance corresponding to deep breathing and heart activity across the chest (17% at 64 kHz, 0.5% at 256 kHz, respectively), on the forearm (0.098% at 16 kHz, 0.04% at 8 kHz), wrist-to-wrist across the body (0.28% at 256 kHz, 0.04% at 256 kHz, respectively), and wrist-to-finger across the body (0.35% at 4 kHz, 0.05% at 4 kHz, respectively). We demonstrate that the wrist-to-wrist and wrist-to-finger configurations are most promising and may enable new wearable bioimpedance applications. Additionally, this paper demonstrates that deep respiration and heart activity influence bioimpedance measurements in whole-body measurement configurations, with variations of nearly 1% in measured impedance due to the phase of the breathing cycle.
使用可穿戴生物传感器实现心肺监测的复杂阻抗谱:一个案例研究
商业上可获得的集成复杂阻抗谱控制器的最新进展使研究人员可用于可穿戴和远程患者监测应用的系统质量迅速提高。因此,新的传感方法和电极配置越来越可行,特别是用于一般电化学分析的低功耗嵌入式传感器和控制器。本研究评估了四种电极位置的案例研究,适用于使用复杂阻抗谱监测呼吸和心脏活动的可穿戴监测。我们使用具有十个刺激频率的四极电极配置来表征测量灵敏度的相对差异。使用两个基于cots的控制器(TI AFE4300和MAX30009)对生物阻抗的幅度、相位、电阻和无功成分进行测量和比较。我们发现,与深呼吸和心脏活动相对应的阻抗大小的相对变化百分比最高,分别是胸部(64 kHz时为17%,256 kHz时为0.5%)、前臂(16 kHz时为0.098%,8 kHz时为0.04%)、全身手腕到手腕(256 kHz时为0.28%,256 kHz时为0.04%)和全身手腕到手指(4 kHz时为0.35%,4 kHz时为0.05%)。我们证明,手腕到手腕和手腕到手指的配置是最有前途的,并可能实现新的可穿戴生物阻抗应用。此外,本文表明,在全身测量配置中,深呼吸和心脏活动影响生物阻抗测量,由于呼吸周期的阶段,测量阻抗的变化接近1%。
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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CiteScore
6.30
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