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Making brain–machine interfaces robust to future neural variability

Author

Listed:
  • David Sussillo

    (Stanford University
    Stanford Neurosciences Institute)

  • Sergey D. Stavisky

    (Neurosciences Graduate Program)

  • Jonathan C. Kao

    (Stanford University)

  • Stephen I. Ryu

    (Stanford University
    Palo Alto Medical Foundation)

  • Krishna V. Shenoy

    (Stanford University
    Stanford Neurosciences Institute
    Neurosciences Graduate Program
    Neurobiology and Bioengineering Departments)

Abstract

A major hurdle to clinical translation of brain–machine interfaces (BMIs) is that current decoders, which are trained from a small quantity of recent data, become ineffective when neural recording conditions subsequently change. We tested whether a decoder could be made more robust to future neural variability by training it to handle a variety of recording conditions sampled from months of previously collected data as well as synthetic training data perturbations. We developed a new multiplicative recurrent neural network BMI decoder that successfully learned a large variety of neural-to-kinematic mappings and became more robust with larger training data sets. Here we demonstrate that when tested with a non-human primate preclinical BMI model, this decoder is robust under conditions that disabled a state-of-the-art Kalman filter-based decoder. These results validate a new BMI strategy in which accumulated data history are effectively harnessed, and may facilitate reliable BMI use by reducing decoder retraining downtime.

Suggested Citation

  • David Sussillo & Sergey D. Stavisky & Jonathan C. Kao & Stephen I. Ryu & Krishna V. Shenoy, 2016. "Making brain–machine interfaces robust to future neural variability," Nature Communications, Nature, vol. 7(1), pages 1-13, December.
    • Handle: RePEc:nat:natcom:v:7:y:2016:i:1:d:10.1038_ncomms13749
    DOI: 10.1038/ncomms13749
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