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一种用于稳定肌电图检测的绝缘柔性传感器:在假肢控制中的应用。

An Insulated Flexible Sensor for Stable Electromyography Detection: Applicationto Prosthesis Control.

机构信息

Institute of Biomedical Mechatronics, Johannes Kepler University, 4040 Linz, Austria.

Research and Development, Otto Bock Healthcare Products GmbH, 1110 Vienna, Austria.

出版信息

Sensors (Basel). 2019 Feb 24;19(4):961. doi: 10.3390/s19040961.

DOI:10.3390/s19040961
PMID:30813504
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6412514/
Abstract

Electromyography (EMG), the measurement of electrical muscle activity, is used in a variety of applications, including myoelectric upper-limb prostheses, which help amputees to regain independence and a higher quality of life. The state-of-the-art sensors in prostheses have a conductive connection to the skin and are therefore sensitive to sweat and require preparation of the skin. They are applied with some pressure to ensure a conductive connection, which may result in pressure marks and can be problematic for patients with circulatory disorders, who constitute a major group of amputees. Due to their insulating layer between skin and sensor area, capacitive sensors are insensitive to the skin condition, they require neither conductive connection to the skin nor electrolytic paste or skin preparation. Here, we describe a highly stable, low-power capacitive EMG measurement set-up that is suitable for real-world application. Various flexible multi-layer sensor set-ups made of copper and insulating foils, flex print and textiles were compared. These flexible sensor set-ups adapt to the anatomy of the human forearm, therefore they provide high wearing comfort and ensure stability against motion artifacts. The influence of the materials used in the sensor set-up on the magnitude of the coupled signal was demonstrated based on both theoretical analysis and measurement.The amplifier circuit was optimized for high signal quality, low power consumption and mobile application. Different shielding and guarding concepts were compared, leading to high SNR.

摘要

肌电图(EMG)是测量肌肉电活动的一种方法,它在多种应用中都有使用,包括帮助截肢者恢复独立和更高生活质量的肌电上肢假肢。假肢中的最先进传感器与皮肤具有导电连接,因此对汗液敏感并且需要对皮肤进行预处理。它们需要施加一定的压力以确保导电连接,这可能会导致压痕,并且对于循环系统障碍患者来说可能会成为问题,这些患者构成了截肢者的主要群体。由于电容传感器在皮肤和传感器区域之间具有绝缘层,因此它们对皮肤状况不敏感,既不需要与皮肤进行导电连接,也不需要使用电解糊或进行皮肤预处理。在这里,我们描述了一种高度稳定、低功耗的电容 EMG 测量设置,适用于实际应用。比较了各种由铜和绝缘箔、挠性印刷电路板和纺织品制成的灵活多层传感器设置。这些灵活的传感器设置适应人体前臂的解剖结构,因此提供了高佩戴舒适度并确保了对运动伪影的稳定性。基于理论分析和测量,证明了传感器设置中使用的材料对耦合信号幅度的影响。放大器电路经过优化,可实现高质量信号、低功耗和移动应用。比较了不同的屏蔽和保护概念,从而实现了高信噪比。

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