Construction and analysis of muscle functional network for exoskeleton robot_Journal of Biomedical Engineering

Authors：

 CHEN Lingling ^1,2 , ZHANG Cun ¹ , SONG Xiaowei ¹ , ZHANG Tengyu ³ , LIU Xiaotian ¹ , YANG Zekun ¹

1. School of Artificial Intelligence, Hebei University of Technology, Tianjin 300130, P.R.China;
2. Engineering Research Center of Intelligent Rehabilitation, Ministry of Education, Tianjin 300130, P.R.China;
3. National Research Center for Rehabilitation Technical Aids, Beijing 100176, P.R.China;

Corresponding author：

CHEN Lingling, Email: chenling@hebut.edu.cn

Keywords：

exoskeleton nursing robot; surface electromyography; muscle functional network; upper extremity muscles; node contraction method

DOI：

10.7507/1001-5515.201803059

Video：

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Abstract Full text Figures/Tables Video References Cited by

Exoskeleton nursing robot is a typical human-machine co-drive system. To full play the subjective control and action orientation of human, it is necessary to comprehensively analyze exoskeleton wearer’s surface electromyography (EMG) in the process of moving patients, especially identifying the spatial distribution and internal relationship of the EMG information. Aiming at the location of electrodes and internal relation between EMG channels, the complex muscle system at the upper limb was abstracted as a muscle functional network. Firstly, the correlation characteristics were analyzed among EMG channels of the upper limb using the mutual information method, so that the muscle function network was established. Secondly, by calculating the characteristic index of network node, the features of muscle function network were analyzed for different movements. Finally, the node contraction method was applied to determine the key muscle group that reflected the intention of wearer’s movement, and the characteristics of muscle function network were analyzed in each stage of moving patients. Experimental results showed that the location of the myoelectric collection could be determined quickly and efficiently, and also various stages of the moving process could effectively be distinguished using the muscle functional network with the key muscle groups. This study provides new ideas and methods to decode the relationship between neural controls of upper limb and physical motion.

Citation： CHEN Lingling, ZHANG Cun, SONG Xiaowei, ZHANG Tengyu, LIU Xiaotian, YANG Zekun. Construction and analysis of muscle functional network for exoskeleton robot. Journal of Biomedical Engineering, 2019, 36(4): 565-572. doi: 10.7507/1001-5515.201803059 Copy

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6.	Teena G, Shalu G K, Sivanandan K S. Processing and application of EMG signals for HAL (Hybrid Assistive Limb)// Proceedings of the 2nd International Conference on Sustainable Energy and Intelligent System. Chennai, Tamil Nadu, India: 2011: 749-753.
7.	Abdulhay E, Khnouf R, Bakeir A, et al. ElectroMyoGram pattern recognition for real-time control of upper limb prosthesis. Journal of Medical Imaging and Health Informatics, 2016, 6(8): 1872-1880.
8.	Kiguchi K, Hayashi Y. An EMG-based control for an upper-limb power-assist exoskeleton robot. IEEE Trans Syst Man Cybern B Cybern, 2012, 42(4): 1064-1071.
9.	Tang Zhichuan, Zhang Kejun, Sun Shouqian, et al. An upper-limb power-assist exoskeleton using proportional myoelectric control. Sensors (Basel), 2014, 14(4): 6677-6694.
10.	Tsai A C, Luh J J, Lin T T. A novel STFT-ranking feature of multi-channel EMG for motion pattern recognition. Expert Syst Appl, 2015, 42(7): 3327-3341.
11.	Geethanjali P. Comparative study of PCA in classification of multichannel EMG signals. Australasian Physical & Engineering Sciences in Medicine, 2015, 38(2): 331-343.
12.	Charoenpanich N, Boonsinsukh R, Sirisup S, et al. Principal component analysis identifies major muscles recruited during elite vertical jump. ScienceAsia, 2013, 39(3): 257-264.
13.	Wirsich J, Perry A, Ridley B, et al. Whole-brain analytic measures of network communication reveal increased structure-function correlation in right temporal lobe epilepsy. Neuroimage Clin, 2016, 11: 707-718.
14.	Young C B, Raz G, Everaerd D, et al. Dynamic shifts in large-scale brain network balance as a function of arousal. J Neurosci, 2017, 37(2): 281-290.
15.	Yin Zhongliang, Li Jun, Zhang Yun, et al. Functional brain network analysis of schizophrenic patients with positive and negative syndrome based on mutual information of EEG time series. Biomed Signal Process Control, 2017, 31: 331-338.
16.	Wang Jiang, Yang Chen, Wang Ruofan, et al. Functional brain networks in Alzheimer's disease: EEG analysis based on limited penetrable visibility graph and phase space method. Physica A: Statistical Mechanics and its Applications, 2016, 460: 174-187.
17.	王甲生, 吴晓平, 廖巍, 等. 改进的加权复杂网络节点重要度评估方法. 计算机工程, 2012, 38(10): 74-76.

1. Huang Zhifeng, Katayama T, Kanai-Pak M, et al. Design and evaluation of robot patient for nursing skill training in patient transfer. Advanced Robotics, 2015, 29(19): 1269-1285.
2. Ding M, Ikeura R, Mori Y, et al. Lift-up motion generation of nursing-care assistant robot based on human muscle force and body softness estimation// IEEE/ASME International Conference on Advanced Intelligent Mechatronics. Besançon, France: IEEE, 2014: 1302-1307.
3. Lobo-Prat J, Kooren P N, Janssen M M, et al. Implementation of EMG- and force-based control interfaces in active elbow supports for men with duchenne muscular dystrophy: a feasibility study. IEEE Trans Neural Syst Rehabil Eng, 2016, 24(11): 1179-1190.
4. Antuvan C W, Bisio F, Marini F, et al. Role of muscle synergies in real-time classification of upper limb motions using extreme learning machines. J Neuroeng Rehabil, 2016, 13(1): 76.
5. 邹晓阳, 雷敏. 基于多尺度模糊熵的动作表面肌电信号模式识别. 生物医学工程学杂志, 2012, 29(6): 1184-1188.
6. Teena G, Shalu G K, Sivanandan K S. Processing and application of EMG signals for HAL (Hybrid Assistive Limb)// Proceedings of the 2nd International Conference on Sustainable Energy and Intelligent System. Chennai, Tamil Nadu, India: 2011: 749-753.
7. Abdulhay E, Khnouf R, Bakeir A, et al. ElectroMyoGram pattern recognition for real-time control of upper limb prosthesis. Journal of Medical Imaging and Health Informatics, 2016, 6(8): 1872-1880.
8. Kiguchi K, Hayashi Y. An EMG-based control for an upper-limb power-assist exoskeleton robot. IEEE Trans Syst Man Cybern B Cybern, 2012, 42(4): 1064-1071.
9. Tang Zhichuan, Zhang Kejun, Sun Shouqian, et al. An upper-limb power-assist exoskeleton using proportional myoelectric control. Sensors (Basel), 2014, 14(4): 6677-6694.
10. Tsai A C, Luh J J, Lin T T. A novel STFT-ranking feature of multi-channel EMG for motion pattern recognition. Expert Syst Appl, 2015, 42(7): 3327-3341.
11. Geethanjali P. Comparative study of PCA in classification of multichannel EMG signals. Australasian Physical & Engineering Sciences in Medicine, 2015, 38(2): 331-343.
12. Charoenpanich N, Boonsinsukh R, Sirisup S, et al. Principal component analysis identifies major muscles recruited during elite vertical jump. ScienceAsia, 2013, 39(3): 257-264.
13. Wirsich J, Perry A, Ridley B, et al. Whole-brain analytic measures of network communication reveal increased structure-function correlation in right temporal lobe epilepsy. Neuroimage Clin, 2016, 11: 707-718.
14. Young C B, Raz G, Everaerd D, et al. Dynamic shifts in large-scale brain network balance as a function of arousal. J Neurosci, 2017, 37(2): 281-290.
15. Yin Zhongliang, Li Jun, Zhang Yun, et al. Functional brain network analysis of schizophrenic patients with positive and negative syndrome based on mutual information of EEG time series. Biomed Signal Process Control, 2017, 31: 331-338.
16. Wang Jiang, Yang Chen, Wang Ruofan, et al. Functional brain networks in Alzheimer's disease: EEG analysis based on limited penetrable visibility graph and phase space method. Physica A: Statistical Mechanics and its Applications, 2016, 460: 174-187.
17. 王甲生, 吴晓平, 廖巍, 等. 改进的加权复杂网络节点重要度评估方法. 计算机工程, 2012, 38(10): 74-76.

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Construction and analysis of muscle functional network for exoskeleton robot

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