Neural Interface Technology for Rehabilitation: Exploiting and Promoting Neuroplasticity

Wei Wang; Jennifer L. Collinger; Monica A. Perez; Elizabeth C. Tyler-Kabara; Leonardo G. Cohen; Niels Birbaumer; Steven W. Brose; Andrew B. Schwartz; Michael L. Boninger; Douglas J. Weber

doi:10.1016/j.pmr.2009.07.003

Neural Interface Technology for Rehabilitation: Exploiting and Promoting Neuroplasticity

Wei Wang, Jennifer L. Collinger, Monica A. Perez, Elizabeth C. Tyler-Kabara, Leonardo G. Cohen, Niels Birbaumer, Steven W. Brose, Andrew B. Schwartz, Michael L. Boninger, Douglas J. Weber

Section of Neuroradiology

Research output: Contribution to journal › Review article › peer-review

164 Scopus citations

Abstract

This article reviews neural interface technology and its relationship with neuroplasticity. Two types of neural interface technology are reviewed, highlighting specific technologies that the authors directly work with: (1) neural interface technology for neural recording, such as the micro-ECoG BCI system for hand prosthesis control, and the comprehensive rehabilitation paradigm combining MEG-BCI, action observation, and motor imagery training; (2) neural interface technology for functional neural stimulation, such as somatosensory neural stimulation for restoring somatosensation, and non-invasive cortical stimulation using rTMS and tDCS for modulating cortical excitability and stroke rehabilitation. The close interaction between neural interface devices and neuroplasticity leads to increased efficacy of neural interface devices and improved functional recovery of the nervous system. This symbiotic relationship between neural interface technology and the nervous system is expected to maximize functional gain for individuals with various sensory, motor, and cognitive impairments, eventually leading to better quality of life.

Original language	English
Pages (from-to)	157-178
Number of pages	22
Journal	Physical Medicine and Rehabilitation Clinics of North America
Volume	21
Issue number	1
DOIs	https://doi.org/10.1016/j.pmr.2009.07.003
State	Published - Feb 2010

Keywords

Brain-computer interface
Neural interface
Neuroplasticity
Recording
Rehabilitation
Stimulation

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Wang, W., Collinger, J. L., Perez, M. A., Tyler-Kabara, E. C., Cohen, L. G., Birbaumer, N., Brose, S. W., Schwartz, A. B., Boninger, M. L., & Weber, D. J. (2010). Neural Interface Technology for Rehabilitation: Exploiting and Promoting Neuroplasticity. Physical Medicine and Rehabilitation Clinics of North America, 21(1), 157-178. https://doi.org/10.1016/j.pmr.2009.07.003

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title = "Neural Interface Technology for Rehabilitation: Exploiting and Promoting Neuroplasticity",

abstract = "This article reviews neural interface technology and its relationship with neuroplasticity. Two types of neural interface technology are reviewed, highlighting specific technologies that the authors directly work with: (1) neural interface technology for neural recording, such as the micro-ECoG BCI system for hand prosthesis control, and the comprehensive rehabilitation paradigm combining MEG-BCI, action observation, and motor imagery training; (2) neural interface technology for functional neural stimulation, such as somatosensory neural stimulation for restoring somatosensation, and non-invasive cortical stimulation using rTMS and tDCS for modulating cortical excitability and stroke rehabilitation. The close interaction between neural interface devices and neuroplasticity leads to increased efficacy of neural interface devices and improved functional recovery of the nervous system. This symbiotic relationship between neural interface technology and the nervous system is expected to maximize functional gain for individuals with various sensory, motor, and cognitive impairments, eventually leading to better quality of life.",

keywords = "Brain-computer interface, Neural interface, Neuroplasticity, Recording, Rehabilitation, Stimulation",

author = "Wei Wang and Collinger, {Jennifer L.} and Perez, {Monica A.} and Tyler-Kabara, {Elizabeth C.} and Cohen, {Leonardo G.} and Niels Birbaumer and Brose, {Steven W.} and Schwartz, {Andrew B.} and Boninger, {Michael L.} and Weber, {Douglas J.}",

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doi = "10.1016/j.pmr.2009.07.003",

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AU - Perez, Monica A.

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AU - Cohen, Leonardo G.

AU - Birbaumer, Niels

AU - Brose, Steven W.

AU - Schwartz, Andrew B.

AU - Boninger, Michael L.

AU - Weber, Douglas J.

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AB - This article reviews neural interface technology and its relationship with neuroplasticity. Two types of neural interface technology are reviewed, highlighting specific technologies that the authors directly work with: (1) neural interface technology for neural recording, such as the micro-ECoG BCI system for hand prosthesis control, and the comprehensive rehabilitation paradigm combining MEG-BCI, action observation, and motor imagery training; (2) neural interface technology for functional neural stimulation, such as somatosensory neural stimulation for restoring somatosensation, and non-invasive cortical stimulation using rTMS and tDCS for modulating cortical excitability and stroke rehabilitation. The close interaction between neural interface devices and neuroplasticity leads to increased efficacy of neural interface devices and improved functional recovery of the nervous system. This symbiotic relationship between neural interface technology and the nervous system is expected to maximize functional gain for individuals with various sensory, motor, and cognitive impairments, eventually leading to better quality of life.

KW - Brain-computer interface

KW - Neural interface

KW - Neuroplasticity

KW - Recording

KW - Rehabilitation

KW - Stimulation

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JO - Physical Medicine and Rehabilitation Clinics of North America

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Neural Interface Technology for Rehabilitation: Exploiting and Promoting Neuroplasticity

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