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手腕运动下的动态肌电解码研究OA

Dynamic electromyography decoding under wrist movements

中文摘要英文摘要

手腕是人体最灵活的部位之一,通过对表面肌电信号(Surface Electromyography,sEMG)进行分解能够有效地解码出人体运动的深层次神经驱动.目前关于手腕力矩的研究大多集中在等长收缩下,动态下的神经驱动解码依然欠缺.本文研究了手腕在不同阻力下运动时的运动单元(Motor Unit,MU)分解,具体来说,通过磁流变阻尼器来设置不同的阻力水平,将采集到的完整肌电信号划分成运动单元动作电位(Motor Unit Action Potential,MUAP)变化微小的短区间,再在每个短区间上使用静态分解算法来获得运动单元尖峰序列(Motor Unit Spike Train,MUST),并通过短区间的重叠部分对MU进行追踪,从而得到完整的发放序列.本文研究了在 20%最大自愿收缩力(Maxi-mum Voluntary Contraction,MVC)、40%MVC、60%MVC三种阻力下,腕部伸展和屈曲时的运动单元分解.结果表明,三种阻力下,本文的动态分解算法能够有效地从小臂肌电信号中分解出MU,随着阻力的增加,分解出的MU数目有所下降.手腕伸展过程最多能分解出 10±1 个 MU,脉冲信噪比(Pulse-to-Noise Ratio,PNR)和轮廓系数(Silhouette Coefficient,SIL)分别能够达到 19.87±1.42 dB和 0.91±0.03,屈曲过程最多能分解出 22±3 个MU,PNR和SIL值分别能够达到 20.69±2.14 dB和 0.92±0.03.本研究表明不同阻力下对手腕运动的肌电信号进行神经解码是可行的,对高密度肌电的动态应用有着重要意义.

The wrist is among the most flexible joints in the human body.Decomposing the surface Electromyogra-phy(sEMG)signals enables the estimation of the deep neural drives underlying human body movements.Current research on wrist moments primarily focuses on isometric contractions,leaving the decoding of neural drives under dynamic conditions an area requiring substantial exploration.This study investigated Motor Unit(MU)decomposi-tion during wrist movements under varying resistance levels,which were precisely controlled using a magnetorheolog-ical damper.The collected continuous electromyography signals were segmented into short intervals where Motor Unit Action Potential(MUAP)waveforms remained relatively stable.Then,a classic decomposition algorithm was applied to each short interval to obtain the Motor Unit Spike Train(MUST),and the MUs were tracked across con-secutive intervals via their overlapping parts to reconstruct complete firing sequences.This paper studied the decom-position of MUs during wrist extension and flexion under three resistance levels:20%,40%,and 60%of the Maxi-mum Voluntary Contraction(MVC).Results showed that the proposed dynamic decomposition algorithm effectively decomposed MUs from forearm sEMG signals,although performance somewhat declined with increasing resistance.During wrist extension,up to 10±1 MUs were decomposed,with Pulse-to-Noise Ratio(PNR)and Silhouette Coeffi-cient(SIL)reaching 19.87±1.42 dB and 0.91±0.03,respectively.While during wrist flexion,up to 22±3 MUs were decomposed,with PNR and SIL values of 20.69±2.14 dB and 0.92±0.03,respectively.This study confirms the feasibility of neural drive decoding from sEMG signals during wrist movements under different resistances,high-lighting significant potential for the application of High-Density sEMG(HD-sEMG)under dynamic muscle contrac-tions.

杨心昊;徐宝国;宋爱国

东南大学 仪器科学与工程学院,南京,210096东南大学 仪器科学与工程学院,南京,210096东南大学 仪器科学与工程学院,南京,210096

信息技术与安全科学

高密度肌电手腕运动运动解码动态分解神经驱动

high-density surface electromyography(HD-sEMG)wrist movementmovement decodingdynamic decompositionneural drive

《南京信息工程大学学报》 2026 (1)

1-10,10

国家重点研发计划(202022YFC2405602)江苏省前沿引领技术基础研究专项(BK20192004A)江苏省自然科学基金(BK20221464)

10.13878/j.cnki.jnuist.20250114002

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