Artificial neural network control of FES in paraplegics for patient responsive ambulation

Describes a binary adaptive resonance theory (ART-1)-based artificial neural network (ANN) adapted for controlling functional electrical stimulation (FES) to facilitate patient-responsive ambulation by paralyzed patients with spinal cord injures. This network is to serve as a controller in an FES system developed by the first author which is presently in use by 300 patients worldwide (still without ANN control) and which was the first and the only FES system approved by the FDA. The proposed neural network discriminates above-lesion upper-trunk electromyographic (EMG) time series to activate standing and walking functions under FES and controls FES stimuli levels using response-EMG signals. For this particular application, the authors introduce several modifications of the ART-1 for pattern recognition and classification. First, a modified on-line learning rule is proposed. The new rule assures bidirectorial modification of the stored patterns and prevents noise interference. Second, a new reset rule is proposed which prevents "exact matching" when the input is a subset of the chosen pattern. The authors show the applicability of a single ART-1-based structure to solving two problems, namely, 1) signal pattern recognition and classification, and 2) control. This also facilitates ambulation of paraplegics under FES, with adequate patient interaction in initial system training, retraining the network when needed, and in allowing patient's manual override in the ease of error, where any manual override serves as a retraining input to the neural network. Thus, the practical control problems (arising in actual independent patient ambulation via FES) were all satisfied by a relatively simple ANN design. >

[1]  Michael Georgiopoulos,et al.  Properties of learning related to pattern diversity in ART1 , 1991, Neural Networks.

[2]  Kambiz Badie,et al.  EMG Pattern Classification Based On Back Propagation Neural Network For Prosthesis Control , 1990, [1990] Proceedings of the Twelfth Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[3]  Thomas W. Ryan,et al.  VARIATIONS ON ADAPTIVE RESONANCE. , 1987 .

[4]  Michael Georgiopoulos,et al.  The N-N-N conjecture in ART1 , 1992, [Proceedings 1992] IJCNN International Joint Conference on Neural Networks.

[5]  Stephen Grossberg,et al.  Competitive Learning: From Interactive Activation to Adaptive Resonance , 1987, Cogn. Sci..

[6]  S. Grossberg,et al.  Probing cognitive processes through the structure of event-related potentials during learning: an experimental and theoretical analysis. , 1987, Applied optics.

[7]  Witold Kinsner,et al.  A Study Of Backpropagation, Counterpropagation, And Adaptive Resonance Theory Neural Network Models , 1990, [1990] Proceedings of the Twelfth Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[8]  William W. Armstrong,et al.  Evaluation of Adaptive Logic Networks for control of walking in paralyzed patients , 1992, 1992 14th Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[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]  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.

[11]  Katsunori Shimohara,et al.  EMG pattern recognition by neural networks for multi fingers control , 1992, 1992 14th Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[12]  Vincent Rialle,et al.  Use of unsupervised neural networks for classification tasks in electromyography , 1992, 1992 14th Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[13]  D. Graupe,et al.  Patient controlled electrical stimulation via EMG signature discrimination for providing certain paraplegics with primitive walking functions. , 1983, Journal of biomedical engineering.

[14]  Michael Georgiopoulos,et al.  The N-N-N conjecture in ART1 , 1992, Neural Networks.

[15]  Stephen Grossberg,et al.  A massively parallel architecture for a self-organizing neural pattern recognition machine , 1988, Comput. Vis. Graph. Image Process..

[16]  T W Ryan,et al.  Dynamic control of an artificial neural system: the property inheritance network. , 1987, Applied optics.