基于三维肌肉协同分析的FES康复效果量化分析

doi:10.3969/j.issn.1000-1158.2024.10.20

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摘要肌肉协同理论能够用于分析神经肌肉系统的内在功能模式,基于此提出了一种基于肌肉协同分析的功能性电刺激(FES)康复效果量化研究方法。首先,在二维肌肉协同分析的基础上,通过连续小波分解建立了肌电张量,利用CP_ALS算法进行了肌电张量的非负矩阵分解,实现了覆盖空域、频域和时域的三维肌肉协同分析。然后,设计了患者腕伸动作康复实验,以健康被试为对照组,分别对比分析了不同偏瘫程度的患者在进行持续10天的FES理疗前后的腕伸肌肉协同变化。实验结果显示经过FES理疗后,患者的肌肉协同数量有所增加(从2增加到3),空域肌肉协同均达到正相关水平(均值为0.5402),频域肌肉协同增幅最大(增幅均值为0.8271),时域肌肉协同效果最好(均值为0.7979),说明FES在卒中康复中能够有效提升患者的肌肉协同效果。

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	杜义浩
	王孝冉
	于金须
	曹添福
	范强

关键词 ：功能性电刺激, 肌肉协同, 小波分解, 肌电张量, CP_ALS, 非负矩阵分解, 康复效果

Abstract：The muscle synergy theory can be used to analyze the intrinsic functional mode of the neuromuscular system, based on which a quantitative research method for FES rehabilitation effect based on muscle synergy analysis is proposed. First, on the basis of two-dimensional muscle synergy analysis, the myoelectric tensor was established by continuous wavelet decomposition, and the non-negative matrix decomposition of the myoelectric tensor was carried out by using the CP_ALS algorithm, so as to realize the three-dimensional muscle synergy analysis covering the null domain, frequency domain and time domain. Then, a patient wrist extension rehabilitation experiment was designed to compare and analyze the changes of wrist extension muscle synergism before and after FES physiotherapy lasting 10 days in patients with different degrees of hemiplegia, using healthy subjects as the control group. The experimental results showed that after FES physical therapy, the number of muscle synergies of patients increased (from 2 to 3), the muscle synergies in the null domain all reached the positive correlation level (mean value of 0.5402), the muscle synergies in the frequency domain had the largest increase (mean value of increase was 0.8271), and the muscle synergies in the temporal domain had the best effect (mean value of 0.7979), which indicated that FES in stroke rehabilitation was able to improve the patients muscle synergy effect.

Key words： FES muscle synergy wavelet decomposition electromyography tensor CP_ALS non-negative matrix factorization rehabilitation effect

收稿日期: 2024-01-11 发布日期: 2024-09-30

PACS:	TP99
	TB973

基金资助:国家自然科学基金(62376241);中央引导地方科技发展资金(自由探索类基础研究)［236Z1804G］;河北省创新能力提升计划(22567619H)

作者简介: 杜义浩(1983- ),河北沧州人,燕山大学副教授,主要从事康复机器人生物反馈控制等方面的研究。Email:duyihao@126.com

引用本文:

杜义浩,王孝冉,于金须,曹添福,范强. 基于三维肌肉协同分析的FES康复效果量化分析[J]. 计量学报, 2024, 45(10): 1576-1584.
DU Yihao,WANG Xiaoran,YU Jinxu,CAO Tianfu,FAN Qiang. Quantitative analysis of FES rehabilitation effects based on three-dimensional muscle synergy analysis. Acta Metrologica Sinica, 2024, 45(10): 1576-1584.

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［5］	李斯. 正常人和脑卒中患者运动的模块化控制分析及应用［D］. 上海: 上海交通大学, 2018.
［24］	KIM Y-D, CHOI S. Nonnegative Tucker Decomposition［C］//2007 IEEE Conference on Computer Vision and Pattern Recognition. 2007: 1-8.
	WANG L D, PENG B, ZHANG H Q, et al. Summary of the China Stroke Prevention and Control Report 2020［J］. Chinese Journal of Cerebrovascular Diseases, 2022, 2(19): 136-144.
［3］	王童. 基于肌肉协同效应的功能性电刺激策略优化及在脑卒中康复中的应用［D］. 上海: 上海交通大学, 2022.
［2］	王陇德, 彭斌, 张鸿祺, 等. 《中国脑卒中防治报告2020》概要［J］. 中国脑血管病杂志, 2022, 2(19): 136-144.
	GUI Q Z, MENG M, MA Y L, et al. Continuous Estimation of Upper Limb Joint Motion Based on Muscle Co-Activation Model［J］. Chinese Journal of Scientific Instrument, 2016, 6(37): 1405-1412.
［9］	ZHOU Y, FANG Y, LIU H. Voluntary and FES-Induced Finger Movement Estimation Using Muscle Deformation Features［J］. IEEE Transactions on Industrial Electronics, 2020, 67(5): 4002-4012.
［11］	SHAHARUDIN S, ZANOTTO D, AGRAWAL S. Muscle Synergies of Untrained Subjects during 6 min Maximal Rowing on Slides and Fixed Ergometer［J］. Journal of Sports Science & Medicine, 2014, 13(4): 793-800.
［13］	ZHAO M, JIA X. A Novel Strategy for Signal Denoising Using Reweighted SVD and Its Applications to Weak Fault Feature Enhancement of Rotating Machinery［J］. Mechanical Systems and Signal Processing, 2017, 94: 129-147.
［15］	WANG Y X. Nonnegative Matrix Factorization: A Comprehensive Review［J］. IEEE Transactions On Knowledge And Data Engineering, 2013, 25(6): 1336-1353.
［18］	DAVELLA A, BIZZI E. Shared and Specific Muscle Synergies in Natural Motor Behaviors［J］. Proceedings of the National Academy of Sciences, 2005, 102(8): 3076-3081.
［20］	TURPIN N A, URIAC S, DALLEAU G. How to Improve the Muscle Synergy Analysis Methodology?［J］. European Journal of Applied Physiology, 2021, 121(4): 1009-1025.
［28］	常清雅. 脑卒中康复运动中肌肉协同特性分析方法研究［D］. 秦皇岛: 燕山大学, 2023.
［7］	程淑红, 杨镇豪, 王唱. 多通道融合下的手势识别算法研究及船舶虚拟交互平台设计［J］. 计量学报, 2022, 43(7): 856-862.
［16］	杨毅, 彭玉鑫, 郝增明, 等. 复杂人体运动冗余控制的肌肉协同理论研究进展与展望［J］. 体育科学, 2020, 40(12): 63-72.
［22］	CONG F, PHAN A H, ZHAO Q, et al. Benefits of Multi-Domain Feature of Mismatch Negativity Extracted by Non-Negative Tensor Factorization from EEG Collected by Low-Density Array［J］. International Journal of Neural Systems, 2012, 22(6): 1250025.
［25］	陈妙慧. 基于非负正交约束的大规模Tucker分解算法［D］. 广州: 华南理工大学, 2021.
［30］	GRACIES J M. Pathophysiology of Spastic Paresis. II: Emergence of Muscle Overactivity ［J］. Muscle & Nerve, 2005, 31(5): 552-571.
［32］	OSUAGWU B A C, WHICHER E, SHIRLEY R. Active Proportional Electromyogram Controlled Functional Electrical Stimulation System［J］. Scientific Reports, 2020, 10(1): 1-15.
［34］	ROUSE C A, DOWNEY R J, GREGORY C M, et al. FES Cycling in Stroke: Novel Closed-Loop Algorithm Accommodates Differences in Functional Impairments［J］. IEEE Transactions on Biomedical Engineering, 2020, 67(3): 738-749.
［1］	XU W, GUO Y, BRAVO C, et al. Design, Control, and Experimental Evaluation of a Novel Robotic Glove System for Patients With Brachial Plexus Injuries［J］. IEEE Transactions on Robotics, 2023, 39(2): 1637-1652.
［6］	桂奇政, 孟明, 马玉良, 等. 基于肌肉协同激活模型的上肢关节运动连续估计［J］. 仪器仪表学报, 2016, 37(6): 1405-1412.
［8］	NIU C M, BAO Y, ZHUANG C, et al. Synergy-Based FES for Post-Stroke Rehabilitation of Upper-Limb Motor Functions［J］. IEEE Transactions on Neural Systems and Rehabilitation Engineering, 2019, 27(2): 256-264.
［14］	LEE D D, SEUNG H S. Learning the Parts of Objects by Non-Negative Matrix Factorization［J］. Nature, 1999, 401(6755): 788-791.
［17］	CHEN X, NIU X, WU D, et al. Investigation of the Intra-and Inter-Limb Muscle Coordination of Hands-and-Knees Crawling in Human Adults by Means of Muscle Synergy Analysis［J］. Entropy, 2017, 19(5): 229-244.
［23］	杨洪礼. 非负矩阵与张量分解及其应用［D］. 青岛: 山东科技大学, 2011.
［27］	杨坤. 青年人和老年人在不同条件骑行时下肢肌肉协同活动特征研究［D］. 上海: 上海体育学院, 2021.
［33］	LI Y, YANG X, ZHOU Y, et al. Adaptive Stimulation Profiles Modulation for Foot Drop Correction Using Functional Electrical Stimulation: A Proof of Concept Study［J］. IEEE Journal of Biomedical and Health Informatics, 2021, 25(1): 59-68.
［35］	DAVELLA A, GIESE M, IVANENKO Y P, et al. Editorial: Modularity in Motor Control: From Muscle Synergies to Cognitive Action Representation［J］. Frontiers in Computational Neuroscience, 2015, 9: 126-141.
［4］	MENG L, BERND PORR, HENRIK GOLLEE, Technical Developments of Functional Electrical Stimulation to Restore Gait Functions: Sensing, Control Strategies and Current Commercial Systems (in English)［J］. Chinese Journal of Scientific Instrument, 2017, 6(38): 1319-1334.
［12］	HYVRINEN A, OJA E. Independent Component Analysis: Algorithms and Applications［J］. Neural Networks, 2000, 13(4): 411-430.
［21］	KOLDA T G, BADER B W. Tensor Decompositions and Applications［J］. SIAM Review, 2009, 51(3): 455-500.
［31］	SCHWARTZMAN G, RAMAMURTI P. Visible Body Human Anatomy Atlas: Innovative Anatomy Learning［J］. Journal of Digital Imaging, 2021, 34(5): 1328-1330.
	CHENG S H, YANG Z H, WANG C, Research on Gesture Recognition Algorithm under Multi-channel Fusion and Design of Ship Virtual Interaction Platform［J］. Acta Metrologica Sinica, 2022, 43(7): 856-862.
［10］	CHEUNG V C K, NIU C M, LI S, et al. A Novel FES Strategy for Poststroke Rehabilitation Based on the Natural Organization of Neuromuscular Control［J］. IEEE Reviews in Biomedical Engineering, 2019, 12: 154-167.
	YANG Y, PENG Y X, HAO Z M, et al. Research Progress and Prospects of Muscle Synergy Theory for Redundant Control of Complex Human Motion ［J］. Sports Science, 2020, 40(12): 63-72.
［19］	李欣欣. 康复功能评价中肌间协同—耦合关系分析方法研究［D］. 秦皇岛: 燕山大学, 2017.
［26］	COMON P, LUCIANI X, ALMEIDA A L F D. Tensor Decompositions, Alternating Least Squares and other Tales［J］. Journal of Chemometrics, 2010, 23(7-8): 393-405.
［29］	黄威. 基于肌肉协同和肌间耦合的上肢运动功能评价方法研究［D］. 杭州: 杭州电子科技大学, 2021.