Decoding a new neural machine interface for control of artificial limbs.

An analysis of the motor control information content made available with a neural-machine interface (NMI) in four subjects is presented in this study. We have developed a novel NMI-called targeted muscle reinnervation (TMR)-to improve the function of artificial arms for amputees. TMR involves transferring the residual amputated nerves to nonfunctional muscles in amputees. The reinnervated muscles act as biological amplifiers of motor commands in the amputated nerves and the surface electromyogram (EMG) can be used to enhance control of a robotic arm. Although initial clinical success with TMR has been promising, the number of degrees of freedom of the robotic arm that can be controlled has been limited by the number of reinnervated muscle sites. In this study we assess how much control information can be extracted from reinnervated muscles using high-density surface EMG electrode arrays to record surface EMG signals over the reinnervated muscles. We then applied pattern classification techniques to the surface EMG signals. High accuracy was achieved in the classification of 16 intended arm, hand, and finger/thumb movements. Preliminary analyses of the required number of EMG channels and computational demands demonstrate clinical feasibility of these methods. This study indicates that TMR combined with pattern-recognition techniques has the potential to further improve the function of prosthetic limbs. In addition, the results demonstrate that the central motor control system is capable of eliciting complex efferent commands for a missing limb, in the absence of peripheral feedback and without retraining of the pathways involved.

[1]  Dario Farina,et al.  Blind separation of linear instantaneous mixtures of nonstationary surface myoelectric signals , 2004, IEEE Transactions on Biomedical Engineering.

[2]  Robert D. Lipschutz,et al.  Targeted reinnervation for enhanced prosthetic arm function in a woman with a proximal amputation: a case study , 2007, The Lancet.

[3]  Robert A. Frosch,et al.  The Advanced Research Projects Agency , 1965 .

[4]  F Trochu,et al.  Nerve cuff electrode with shape memory alloy armature: design and fabrication. , 2002, Bio-medical materials and engineering.

[5]  Todd A. Kuiken,et al.  Simulation of Intramuscular EMG Signals Detected Using Implantable Myoelectric Sensors (IMES) , 2006, IEEE Transactions on Biomedical Engineering.

[6]  J. Stewart,et al.  Peripheral nerve fascicles: Anatomy and clinical relevance , 2003, Muscle & nerve.

[7]  Junuk Chu,et al.  A Real-Time EMG Pattern Recognition System Based on Linear-Nonlinear Feature Projection for a Multifunction Myoelectric Hand , 2006, IEEE Transactions on Biomedical Engineering.

[8]  Julius T. Tou,et al.  Pattern Recognition Principles , 1974 .

[9]  R. Scott,et al.  Myoelectric control of prostheses. , 1986, Critical reviews in biomedical engineering.

[10]  K. Englehart,et al.  Classification of the myoelectric signal using time-frequency based representations. , 1999, Medical engineering & physics.

[11]  Robert D. Lipschutz,et al.  Improved Myoelectric Prosthesis Control Accomplished Using Multiple Nerve Transfers , 2006, Plastic and reconstructive surgery.

[12]  P WEISS,et al.  Competitive reinnervation of rat muscles by their own and foreign nerves. , 1946, Journal of neurophysiology.

[13]  D. Wolpert Computational approaches to motor control , 1997, Trends in Cognitive Sciences.

[14]  Todd A. Kuiken,et al.  The hyper-reinnervation of rat skeletal muscle , 1995, Brain Research.

[15]  Robert D. Lipschutz,et al.  The use of targeted muscle reinnervation for improved myoelectric prosthesis control in a bilateral shoulder disarticulation amputee , 2004, Prosthetics and orthotics international.

[16]  Á. Pascual-Leone,et al.  Reorganization of human cortical motor output maps following traumatic forearm amputation , 1996, Neuroreport.

[17]  Xin Zhang,et al.  Noninvasive localization of the site of origin of paced cardiac activation in human by means of a 3-D heart model , 2003, IEEE Transactions on Biomedical Engineering.

[18]  G. E. Loeb,et al.  Implantable electrical and mechanical interfaces with nerve and muscle , 2006, Annals of Biomedical Engineering.

[19]  Pavel Paclík,et al.  Adaptive floating search methods in feature selection , 1999, Pattern Recognit. Lett..

[20]  T. Stieglitz,et al.  A biohybrid system to interface peripheral nerves after traumatic lesions: design of a high channel sieve electrode. , 2002, Biosensors & bioelectronics.

[21]  Adrian D. C. Chan,et al.  A Gaussian mixture model based classification scheme for myoelectric control of powered upper limb prostheses , 2005, IEEE Transactions on Biomedical Engineering.

[22]  D Graupe,et al.  Multifunctional prosthesis and orthosis control via microcomputer identification of temporal pattern differences in single-site myoelectric signals. , 1982, Journal of biomedical engineering.

[23]  Eduardo Fernández,et al.  Long-term stimulation and recording with a penetrating microelectrode array in cat sciatic nerve , 2004, IEEE Transactions on Biomedical Engineering.

[24]  G E Loeb,et al.  BION system for distributed neural prosthetic interfaces. , 2001, Medical engineering & physics.

[25]  Levi J. Hargrove,et al.  A Comparison of Surface and Intramuscular Myoelectric Signal Classification , 2007, IEEE Transactions on Biomedical Engineering.

[26]  Kevin B. Englehart,et al.  A robust, real-time control scheme for multifunction myoelectric control , 2003, IEEE Transactions on Biomedical Engineering.

[27]  R.N. Scott,et al.  A new strategy for multifunction myoelectric control , 1993, IEEE Transactions on Biomedical Engineering.

[28]  R. Stein Nerve and Muscle: Membranes, Cells, and Systems , 1980 .

[29]  Todd A. Kuiken,et al.  TRANSHUMERAL LEVEL FITTING AND OUTCOMES FOLLOWING TARGETED HYPER-REINNERVATION NERVE TRANSFER SURGERY , 2005 .

[30]  Todd A. Kuiken,et al.  Consideration of nerve-muscle grafts to improve the control of artificial arms , 2003 .