Recasting Brain-machine Interface Design from a Physical Control System Perspective

Overview

Journal J Comput Neurosci

Specialties Biology
Neurology

Date 2015 Jul 6

PMID 26142906

Citations 7

Authors

Yin Zhang

Steven M Chase

Affiliations

Soon will be listed here.

Abstract

With the goal of improving the quality of life for people suffering from various motor control disorders, brain-machine interfaces provide direct neural control of prosthetic devices by translating neural signals into control signals. These systems act by reading motor intent signals directly from the brain and using them to control, for example, the movement of a cursor on a computer screen. Over the past two decades, much attention has been devoted to the decoding problem: how should recorded neural activity be translated into the movement of the cursor? Most approaches have focused on this problem from an estimation standpoint, i.e., decoders are designed to return the best estimate of motor intent possible, under various sets of assumptions about how the recorded neural signals represent motor intent. Here we recast the decoder design problem from a physical control system perspective, and investigate how various classes of decoders lead to different types of physical systems for the subject to control. This framework leads to new interpretations of why certain types of decoders have been shown to perform better than others. These results have implications for understanding how motor neurons are recruited to perform various tasks, and may lend insight into the brain's ability to conceptualize artificial systems.

Citing Articles

Less is more: selection from a small set of options improves BCI velocity control.

Alcolea P, Ma X, Bodkin K, Miller L, Danziger Z bioRxiv. 2024; .

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Neural Plasticity in Sensorimotor Brain-Machine Interfaces.

Dadarlat M, Canfield R, Orsborn A Annu Rev Biomed Eng. 2023; 25:51-76.

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Distributed processing of movement signaling.

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Brain-machine interface cursor position only weakly affects monkey and human motor cortical activity in the absence of arm movements.

Stavisky S, Kao J, Nuyujukian P, Pandarinath C, Blabe C, Ryu S Sci Rep. 2018; 8(1):16357.

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The critical stability task: quantifying sensory-motor control during ongoing movement in nonhuman primates.

Quick K, Mischel J, Loughlin P, Batista A J Neurophysiol. 2018; 120(5):2164-2181.

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