Exploring the mechanism of neural-function reconstruction by reinnervated nerves in targeted muscles

A lack of myoelectric sources after limb amputation is a critical challenge in the control of multifunctional motorized prostheses. To reconstruct myoelectric sources physiologically related to lost limbs, a newly proposed neural-function construc- tion method, targeted muscle reinnervation (TMR), a...

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Published inFrontiers of information technology & electronic engineering Vol. 15; no. 10; pp. 813 - 820
Main Authors Zhou, Hui, Yang, Lin, Wu, Feng-xia, Huang, Jian-ping, Zhang, Liang-qing, Yang, Ying-jian, Li, Guang-lin
Format Journal Article
LanguageEnglish
Published Heidelberg Zhejiang University Press 01.10.2014
Springer Nature B.V
Subjects
Communications Engineering
Computer Hardware
Computer Science
Computer Systems Organization and Communication Networks
Electrical Engineering
Electronics and Microelectronics
Instrumentation
Median nerve
Muscles
Myoelectricity
Networks
Prostheses
Surgery
Target acquisition
Myoelectric prostheses
Targeted muscle reinnervation
TP212.3
Neural function reconstruction
Q189
Intramuscular myoelectric signal
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Summary:A lack of myoelectric sources after limb amputation is a critical challenge in the control of multifunctional motorized prostheses. To reconstruct myoelectric sources physiologically related to lost limbs, a newly proposed neural-function construc- tion method, targeted muscle reinnervation (TMR), appears promising. Recent advances in the TMR technique suggest that TMR could provide additional motor command information for the control of multifimctional myoelectric prostheses. However, little is known about the nature of the physiological functional recovery of the reinnervated muscles. More understanding of the under- lying mechanism of TMR could help us fine tune the technique to maximize its capability to achieve a much higher performance in the control of multifunctional prostheses. In this study, rats were used as an animal model for TMR surgery involving transferring a median nerve into the pectoralis major, which served as the target muscle. Intramuscular myoelectric signals reconstructed following TMR were recorded by implanted wire electrodes and analyzed to explore the nature of the neural-fimction recon- struction achieved by reinnervation of targeted muscles. Our results showed that the active myoelectric signal reconstructed in the targeted muscle was acquired one week after TMR surgery, and its amplitude gradually became stronger over time. These pre- liminary results from rats may serve as a basis for exploring the mechanism of neural-function reconstruction by the TMR tech- nique in human subjects.
Bibliography:Neural function reconstruction, Targeted muscle reinnervation, Intramuscular myoelectric signal, Myoelectri~prostheses /
A lack of myoelectric sources after limb amputation is a critical challenge in the control of multifunctional motorized prostheses. To reconstruct myoelectric sources physiologically related to lost limbs, a newly proposed neural-function construc- tion method, targeted muscle reinnervation (TMR), appears promising. Recent advances in the TMR technique suggest that TMR could provide additional motor command information for the control of multifimctional myoelectric prostheses. However, little is known about the nature of the physiological functional recovery of the reinnervated muscles. More understanding of the under- lying mechanism of TMR could help us fine tune the technique to maximize its capability to achieve a much higher performance in the control of multifunctional prostheses. In this study, rats were used as an animal model for TMR surgery involving transferring a median nerve into the pectoralis major, which served as the target muscle. Intramuscular myoelectric signals reconstructed following TMR were recorded by implanted wire electrodes and analyzed to explore the nature of the neural-fimction recon- struction achieved by reinnervation of targeted muscles. Our results showed that the active myoelectric signal reconstructed in the targeted muscle was acquired one week after TMR surgery, and its amplitude gradually became stronger over time. These pre- liminary results from rats may serve as a basis for exploring the mechanism of neural-function reconstruction by the TMR tech- nique in human subjects.
ISSN:1869-1951
2095-9184
1869-196X
2095-9230
DOI:10.1631/jzus.C1400154