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Deep Learning for Enhanced Prosthetic Control: Real-Time Motor Intent Decoding for Simultaneous Control of Artificial

Jan Zbinden, Julia Molin, Max Ortiz-Catalan

    IEEE Transactions on Neural Systems and Rehabilitation Engineering : a Publication of the IEEE Engineering in Medicine and Biology Society
    |February 29, 2024
    PubMed
    Summary
    This summary is machine-generated.

    Deep learning models significantly improve prosthetic control by accurately decoding motor intent from electromyography (EMG) signals. This advancement offers more precise and reliable prosthetic functionality for amputees.

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    Area of Science:

    • Rehabilitation Engineering
    • Biomedical Signal Processing
    • Artificial Intelligence in Healthcare

    Background:

    • Advanced prosthetic devices require seamless integration with daily life.
    • Decoding motor intent from electromyography (EMG) signals is crucial for intuitive prosthetic control.
    • Shallow neural networks have limitations in capturing complex EMG signal patterns.

    Purpose of the Study:

    • To compare the performance of deep learning architectures against shallow networks for motor intent decoding.
    • To evaluate the effectiveness of different neural network models in real-time prosthetic control.
    • To assess the generalizability of deep learning models across different user groups.

    Main Methods:

    • Four neural network architectures were evaluated: shallow feedforward, deep feedforward, temporal convolutional network, and convolutional neural network with squeeze-and-excitation.
    • Real-time, human-in-the-loop experiments were conducted with able-bodied participants and an individual with an amputation.
    • Electromyography (EMG) signals were used to decode motor intent.

    Main Results:

    • Deep learning architectures significantly outperformed shallow networks in decoding motor intent.
    • Representation learning within deep networks effectively extracted motor control information from EMG signals.
    • Performance improvements using deep neural networks were consistent across both able-bodied and amputee participants.

    Conclusions:

    • Deep neural networks offer superior performance for prosthetic control compared to shallow networks.
    • Enhanced motor intent decoding using deep learning can lead to more reliable and precise prosthetic functionality.
    • This approach has the potential to significantly improve prosthetic capabilities and quality of life for individuals with amputations.