一种用于轻瘫的基于混合体重指数的外骨骼：用于辅助手臂运动的肌电图控制。

A hybrid BMI-based exoskeleton for paresis: EMG control for assisting arm movements.

作者信息

Kawase Toshihiro, Sakurada Takeshi, Koike Yasuharu, Kansaku Kenji

机构信息

Systems Neuroscience Section, Department of Rehabilitation for Brain Functions, Research Institute of National Rehabilitation Center for Persons with Disabilities, 4-1 Namiki, Tokorozawa, Saitama 359-8555, Japan. Biointerfaces Unit, Institute of Innovative Research, Tokyo Institute of Technology, 4259 Nagatsuta, Midori, Yokohama, Kanagawa 226-8503, Japan.

出版信息

J Neural Eng. 2017 Feb;14(1):016015. doi: 10.1088/1741-2552/aa525f. Epub 2017 Jan 9.

DOI:10.1088/1741-2552/aa525f

PMID:28068293

Abstract

OBJECTIVE

Brain-machine interface (BMI) technologies have succeeded in controlling robotic exoskeletons, enabling some paralyzed people to control their own arms and hands. We have developed an exoskeleton asynchronously controlled by EEG signals. In this study, to enable real-time control of the exoskeleton for paresis, we developed a hybrid system with EEG and EMG signals, and the EMG signals were used to estimate its joint angles.

APPROACH

Eleven able-bodied subjects and two patients with upper cervical spinal cord injuries (SCIs) performed hand and arm movements, and the angles of the metacarpophalangeal (MP) joint of the index finger, wrist, and elbow were estimated from EMG signals using a formula that we derived to calculate joint angles from EMG signals, based on a musculoskeletal model. The formula was exploited to control the elbow of the exoskeleton after automatic adjustments. Four able-bodied subjects and a patient with upper cervical SCI wore an exoskeleton controlled using EMG signals and were required to perform hand and arm movements to carry and release a ball.

MAIN RESULTS

Estimated angles of the MP joints of index fingers, wrists, and elbows were correlated well with the measured angles in 11 able-bodied subjects (correlation coefficients were 0.81 ± 0.09, 0.85 ± 0.09, and 0.76 ± 0.13, respectively) and the patients (e.g. 0.91 ± 0.01 in the elbow of a patient). Four able-bodied subjects successfully positioned their arms to adequate angles by extending their elbows and a joint of the exoskeleton, with root-mean-square errors <6°. An upper cervical SCI patient, empowered by the exoskeleton, successfully carried a ball to a goal in all 10 trials.

SIGNIFICANCE

A BMI-based exoskeleton for paralyzed arms and hands using real-time control was realized by designing a new method to estimate joint angles based on EMG signals, and these may be useful for practical rehabilitation and the support of daily actions.

摘要

目的

脑机接口（BMI）技术已成功用于控制机器人外骨骼，使一些瘫痪患者能够控制自己的手臂和手部。我们开发了一种由脑电图（EEG）信号异步控制的外骨骼。在本研究中，为实现对轻瘫患者外骨骼的实时控制，我们开发了一种结合EEG和肌电图（EMG）信号的混合系统，并使用EMG信号来估计其关节角度。

方法

11名身体健全的受试者和2名上颈段脊髓损伤（SCI）患者进行手部和手臂运动，基于肌肉骨骼模型，使用我们推导的从EMG信号计算关节角度的公式，从EMG信号中估计食指掌指（MP）关节、腕关节和肘关节的角度。在自动调整后，利用该公式控制外骨骼的肘部。4名身体健全的受试者和1名上颈段SCI患者佩戴由EMG信号控制的外骨骼，并被要求进行手部和手臂运动以拿起和放下一个球。

主要结果

在11名身体健全的受试者（相关系数分别为0.81±0.09、0.85±0.09和0.76±0.13）和患者（如一名患者肘部的相关系数为0.91±0.01）中，食指、腕部和肘部MP关节的估计角度与测量角度相关性良好。4名身体健全的受试者通过伸展肘部和外骨骼的一个关节成功将手臂定位到合适角度，均方根误差<6°。一名上颈段SCI患者在外骨骼的助力下，在所有10次试验中均成功将球运至目标位置。

意义

通过设计一种基于EMG信号估计关节角度的新方法，实现了一种用于瘫痪手臂和手部的基于BMI的实时控制外骨骼，这可能对实际康复和日常活动支持有用。

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一种用于轻瘫的基于混合体重指数的外骨骼：用于辅助手臂运动的肌电图控制。

A hybrid BMI-based exoskeleton for paresis: EMG control for assisting arm movements.

作者信息

机构信息

出版信息

OBJECTIVE

APPROACH

MAIN RESULTS

SIGNIFICANCE

目的

方法

主要结果

意义

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