EMG-based prediction of shoulder and elbow kinematics in able-bodied and spinal cord injured individuals.

We have evaluated the ability of a time-delayed artificial neural network (TDANN) to predict shoulder and elbow motions using only electromyographic (EMG) signals recorded from six shoulder and elbow muscles as inputs, both in able-bodied subjects and in subjects with tetraplegia arising from C5 spinal cord injury. For able-bodied subjects, all four joint angles (elbow flexion-extension and shoulder horizontal flexion-extension, elevation-depression, and internal-external rotation) were predicted with average root-mean-square (rms) errors of less than 20 degrees during movements of widely different complexities performed at different speeds and with different hand loads. The corresponding angular velocities and angular accelerations were predicted with even lower relative errors. For individuals with C5 tetraplegia, the absolute rms errors of the joint angles, velocities, and accelerations were actually smaller than for able-bodied subjects, but the relative errors were similar when the smaller movement ranges of the C5 subjects were taken into account. These results indicate that the EMG signals from shoulder and elbow muscles contain a significant amount of information about arm moVement kinematics that could be exploited to develop advanced control systems for augmenting or restoring shoulder and elbow movements to individuals with tetraplegia using functional neuromuscular stimulation of paralyzed muscles.

[1]  J. E. Bateman,et al.  The shoulder and neck , 1972 .

[2]  George N. Saridis,et al.  EMG Pattern Analysis and Classification for a Prosthetic Arm , 1982, IEEE Transactions on Biomedical Engineering.

[3]  E S Grood,et al.  A joint coordinate system for the clinical description of three-dimensional motions: application to the knee. , 1983, Journal of biomechanical engineering.

[4]  G. Hefftner,et al.  The electromyogram (EMG) as a control signal for functional neuromuscular stimulation. I. Autoregressive modeling as a means of EMG signature discrimination , 1988, IEEE Transactions on Biomedical Engineering.

[5]  G. Hefftner,et al.  The electromyogram (EMG) as a control signal for functional neuromuscular stimulation. II. Practical demonstration of the EMG signature discrimination system , 1988, IEEE Transactions on Biomedical Engineering.

[6]  R.J. Triolo,et al.  The experimental demonstration of a multichannel time-series myoprocessor: system testing and evaluation , 1989, IEEE Transactions on Biomedical Engineering.

[7]  P.H. Peckham,et al.  Elbow extension in the C5 quadriplegic using functional neuromuscular stimulation , 1989, IEEE Transactions on Biomedical Engineering.

[8]  R.J. Triolo,et al.  The theoretical development of a multichannel time-series myoprocessor for simultaneous limb function detection and muscle force estimation , 1989, IEEE Transactions on Biomedical Engineering.

[9]  D. Graupe EMG pattern analysis for patient-responsive control of FES in paraplegics for walker-supported walking , 1989, IEEE Transactions on Biomedical Engineering.

[10]  Stephen C. Jacobsen,et al.  Model-Based, Multi-Muscle EMG Control of Upper-Extremity Prostheses , 1990 .

[11]  R.N. Scott,et al.  The application of neural networks to myoelectric signal analysis: a preliminary study , 1990, IEEE Transactions on Biomedical Engineering.

[12]  S. Meek,et al.  Comparison of signal-to-noise ratio of myoelectric filters for prosthesis control. , 1992, Journal of rehabilitation research and development.

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

[14]  P E Patterson,et al.  Identification of lower arm motions using the EMG signals of shoulder muscles. , 1994, Medical engineering & physics.

[15]  Euljoon Park,et al.  Adaptive filtering of the electromyographic signal for prosthetic control and force estimation , 1995, IEEE Transactions on Biomedical Engineering.

[16]  Bruce C. Wheeler,et al.  EMG feature evaluation for movement control of upper extremity prostheses , 1995 .

[17]  P H Chappell,et al.  Real time microcontroller implementation of an adaptive myoelectric filter. , 1995, Medical engineering & physics.

[18]  Daniel Graupe,et al.  Artificial neural network control of FES in paraplegics for patient responsive ambulation , 1995 .

[19]  G. Cheron,et al.  A dynamic neural network identification of electromyography and arm trajectory relationship during complex movements , 1996, IEEE Transactions on Biomedical Engineering.

[20]  P. Crago,et al.  Restoration of pronosupination control by FNS in tetraplegia--experimental and biomechanical evaluation of feasibility. , 1996, Journal of biomechanics.

[21]  M W Keith,et al.  An elbow extension neuroprosthesis for individuals with tetraplegia. , 1998, IEEE transactions on rehabilitation engineering : a publication of the IEEE Engineering in Medicine and Biology Society.

[22]  P H Peckham,et al.  A comparison between control methods for implanted FES hand-grasp systems. , 1998, IEEE transactions on rehabilitation engineering : a publication of the IEEE Engineering in Medicine and Biology Society.