THE SCIENCE AND ENGINEERING BEHIND SENSITIZED BRAIN-CONTROLLED BIONIC HANDS

Chethan Pandarinath; Sliman J Bensmaia

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Author Notes:

S. J. Bensmaia, sliman@uchicago.edu

C. Pandarinath, chethan@gatech.edu

C.P. and S.J.B. drafted manuscript; edited and revised manuscript; and approved final version of manuscript.

We thank Frank Willett for discussions on human motor cortical anatomy, Jonathan Kao and Frank Willett for discussions on decoding architectures, Krishna Shenoy, Sergey Stavisky, Paul Nuyujukian, Frank Willett, Jennifer Collinger, and Robert Gaunt for discussions on performance measurements, Marc Slutzky, David Brandman, Jaimie Henderson, Erin Buckley, Sumner Norman, Vikash Gilja, Amy Orsborn, and Sylvain Baillet for discussions on neural interfaces, Saurabh Vyas, Sergey Stavisky, and Kevin Otto for comments on the manuscript, and Ashley van Driesche for help with figure preparation.

No conflicts of interest, financial or otherwise, are declared by the authors.

Subjects:

Keywords:

Science & Technology
Life Sciences & Biomedicine
Physiology
artificial touch
brain-machine interfaces
motor control
neuroprosthetics
sensory feedback
PRIMARY MOTOR CORTEX
SPINAL-CORD-INJURY
POSTERIOR PARIETAL CORTEX
LOCAL-FIELD POTENTIALS
CHRONIC NEURAL INTERFACE
OF-THE-ART
COMPUTER INTERFACE
MACHINE INTERFACE
PREMOTOR CORTEX
UPPER-LIMB

THE SCIENCE AND ENGINEERING BEHIND SENSITIZED BRAIN-CONTROLLED BIONIC HANDS

Chethan Pandarinath, Emory University

Sliman J Bensmaia, University of Chicago

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Journal Title:

PHYSIOLOGICAL REVIEWS

Volume:

Volume 102, Number 2

Publisher:

AMER PHYSIOLOGICAL SOC | 2022-04-01, Pages 551-604

Type of Work:

Article | Final Publisher PDF

Permanent URL:

https://pid.emory.edu/ark:/25593/w695x

Publisher DOI:

http://doi.org/10.1152/physrev.00034.2020

Abstract:

Advances in our understanding of brain function, along with the development of neural interfaces that allow for the monitoring and activation of neurons, have paved the way for brain-machine interfaces (BMIs), which harness neural signals to reanimate the limbs via electrical activation of the muscles or to control extracorporeal devices, thereby bypassing the muscles and senses altogether. BMIs consist of reading out motor intent from the neuronal responses monitored in motor regions of the brain and executing intended movements with bionic limbs, reanimated limbs, or exoskeletons. BMIs also allow for the restoration of the sense of touch by electrically activating neurons in somatosensory regions of the brain, thereby evoking vivid tactile sensations and conveying feedback about object interactions. In this review, we discuss the neural mechanisms of motor control and somatosensation in able-bodied individuals and describe approaches to use neuronal responses as control signals for movement restoration and to activate residual sensory pathways to restore touch. Although the focus of the review is on intracortical approaches, we also describe alternative signal sources for control and noninvasive strategies for sensory restoration.

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THE SCIENCE AND ENGINEERING BEHIND SENSITIZED BRAIN-CONTROLLED BIONIC HANDS

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