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Making brain-machine interfaces robust to future neural variability

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 datasets. When tested with a non-human primate preclinical BMI model, this decoder was 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 is effectively harnessed, and may facilitate reliable daily BMI use by reducing decoder retraining downtime.

preprint2016arXivOpen access
David SussilloSergey D. StaviskyJonathan C. KaoStephen I. RyuKrishna V. Shenoy
Machine LearningNeurons and Cognition
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Open access5 authors2 topics
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David SussilloSergey D. StaviskyJonathan C. KaoStephen I. RyuKrishna V. Shenoy

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