Novel intraoperative online functional mapping of somatosensory finger representations for targeted stimulating electrode placement: technical note

David P. McMullen; Tessy M. Thomas; Matthew S. Fifer; Daniel N. Candrea; Francesco V. Tenore; Robert W. Nickl; Eric A. Pohlmeyer; Christopher Coogan; Luke E. Osborn; Adam Schiavi; Teresa Wojtasiewicz; Chad R. Gordon; Adam B. Cohen; Nick F. Ramsey; Wouter Schellekens; Sliman J. Bensmaia; Gabriela L. Cantarero; Pablo A. Celnik; Brock A. Wester; William S. Anderson; Nathan E. Crone

doi:10.3171/2020.9.JNS202675

Novel intraoperative online functional mapping of somatosensory finger representations for targeted stimulating electrode placement: technical note

David P. McMullen, Tessy M. Thomas, Matthew S. Fifer, Daniel N. Candrea, Francesco V. Tenore, Robert W. Nickl, Eric A. Pohlmeyer, Christopher Coogan, Luke E. Osborn, Adam Schiavi, Teresa Wojtasiewicz, Chad R. Gordon, Adam B. Cohen, Nick F. Ramsey, Wouter Schellekens, Sliman J. Bensmaia, Gabriela L. Cantarero, Pablo A. Celnik, Brock A. Wester, William S. AndersonNathan E. Crone

Physical Medicine and Rehabilitation

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

Defining eloquent cortex intraoperatively, traditionally performed by neurosurgeons to preserve patient function, can now help target electrode implantation for restoring function. Brain-machine interfaces (BMIs) have the potential to restore upper-limb motor control to paralyzed patients but require accurate placement of recording and stimulating electrodes to enable functional control of a prosthetic limb. Beyond motor decoding from recording arrays, precise placement of stimulating electrodes in cortical areas associated with finger and fingertip sensations allows for the delivery of sensory feedback that could improve dexterous control of prosthetic hands. In this study, the authors demonstrated the use of a novel intraoperative online functional mapping (OFM) technique with high-density electrocorticography to localize finger representations in human primary somatosensory cortex. In conjunction with traditional pre- and intraoperative targeting approaches, this technique enabled accurate implantation of stimulating microelectrodes, which was confirmed by postimplantation intracortical stimulation of finger and fingertip sensations. This work demonstrates the utility of intraoperative OFM and will inform future studies of closed-loop BMIs in humans.

Original language	English (US)
Pages (from-to)	1493-1500
Number of pages	8
Journal	Journal of neurosurgery
Volume	135
Issue number	5
DOIs	https://doi.org/10.3171/2020.9.JNS202675
State	Published - Mar 26 2021

Keywords

brain-computer interface
brain-machine interface
ECoG
electrocorticography
epilepsy
intracortical microstimulation
intraoperative functional mapping
MEA
microelectrode array
online functional mapping
surgical technique

ASJC Scopus subject areas

Surgery
Clinical Neurology

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McMullen, D. P., Thomas, T. M., Fifer, M. S., Candrea, D. N., Tenore, F. V., Nickl, R. W., Pohlmeyer, E. A., Coogan, C., Osborn, L. E., Schiavi, A., Wojtasiewicz, T., Gordon, C. R., Cohen, A. B., Ramsey, N. F., Schellekens, W., Bensmaia, S. J., Cantarero, G. L., Celnik, P. A., Wester, B. A., ... Crone, N. E. (2021). Novel intraoperative online functional mapping of somatosensory finger representations for targeted stimulating electrode placement: technical note. Journal of neurosurgery, 135(5), 1493-1500. https://doi.org/10.3171/2020.9.JNS202675

@article{c1c09d625d474413ad48afebb03577c8,

title = "Novel intraoperative online functional mapping of somatosensory finger representations for targeted stimulating electrode placement: technical note",

abstract = "Defining eloquent cortex intraoperatively, traditionally performed by neurosurgeons to preserve patient function, can now help target electrode implantation for restoring function. Brain-machine interfaces (BMIs) have the potential to restore upper-limb motor control to paralyzed patients but require accurate placement of recording and stimulating electrodes to enable functional control of a prosthetic limb. Beyond motor decoding from recording arrays, precise placement of stimulating electrodes in cortical areas associated with finger and fingertip sensations allows for the delivery of sensory feedback that could improve dexterous control of prosthetic hands. In this study, the authors demonstrated the use of a novel intraoperative online functional mapping (OFM) technique with high-density electrocorticography to localize finger representations in human primary somatosensory cortex. In conjunction with traditional pre- and intraoperative targeting approaches, this technique enabled accurate implantation of stimulating microelectrodes, which was confirmed by postimplantation intracortical stimulation of finger and fingertip sensations. This work demonstrates the utility of intraoperative OFM and will inform future studies of closed-loop BMIs in humans.",

keywords = "brain-computer interface, brain-machine interface, ECoG, electrocorticography, epilepsy, intracortical microstimulation, intraoperative functional mapping, MEA, microelectrode array, online functional mapping, surgical technique",

author = "McMullen, {David P.} and Thomas, {Tessy M.} and Fifer, {Matthew S.} and Candrea, {Daniel N.} and Tenore, {Francesco V.} and Nickl, {Robert W.} and Pohlmeyer, {Eric A.} and Christopher Coogan and Osborn, {Luke E.} and Adam Schiavi and Teresa Wojtasiewicz and Gordon, {Chad R.} and Cohen, {Adam B.} and Ramsey, {Nick F.} and Wouter Schellekens and Bensmaia, {Sliman J.} and Cantarero, {Gabriela L.} and Celnik, {Pablo A.} and Wester, {Brock A.} and Anderson, {William S.} and Crone, {Nathan E.}",

year = "2021",

month = mar,

day = "26",

doi = "10.3171/2020.9.JNS202675",

language = "English (US)",

volume = "135",

pages = "1493--1500",

journal = "Journal of neurosurgery",

issn = "0022-3085",

publisher = "American Association of Neurological Surgeons",

number = "5",

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McMullen, DP, Thomas, TM, Fifer, MS, Candrea, DN, Tenore, FV, Nickl, RW, Pohlmeyer, EA, Coogan, C, Osborn, LE, Schiavi, A, Wojtasiewicz, T, Gordon, CR, Cohen, AB, Ramsey, NF, Schellekens, W, Bensmaia, SJ, Cantarero, GL, Celnik, PA, Wester, BA, Anderson, WS & Crone, NE 2021, 'Novel intraoperative online functional mapping of somatosensory finger representations for targeted stimulating electrode placement: technical note', Journal of neurosurgery, vol. 135, no. 5, pp. 1493-1500. https://doi.org/10.3171/2020.9.JNS202675

TY - JOUR

T1 - Novel intraoperative online functional mapping of somatosensory finger representations for targeted stimulating electrode placement

T2 - technical note

AU - McMullen, David P.

AU - Thomas, Tessy M.

AU - Fifer, Matthew S.

AU - Candrea, Daniel N.

AU - Tenore, Francesco V.

AU - Nickl, Robert W.

AU - Pohlmeyer, Eric A.

AU - Coogan, Christopher

AU - Osborn, Luke E.

AU - Schiavi, Adam

AU - Wojtasiewicz, Teresa

AU - Gordon, Chad R.

AU - Cohen, Adam B.

AU - Ramsey, Nick F.

AU - Schellekens, Wouter

AU - Bensmaia, Sliman J.

AU - Cantarero, Gabriela L.

AU - Celnik, Pablo A.

AU - Wester, Brock A.

AU - Anderson, William S.

AU - Crone, Nathan E.

PY - 2021/3/26

Y1 - 2021/3/26

N2 - Defining eloquent cortex intraoperatively, traditionally performed by neurosurgeons to preserve patient function, can now help target electrode implantation for restoring function. Brain-machine interfaces (BMIs) have the potential to restore upper-limb motor control to paralyzed patients but require accurate placement of recording and stimulating electrodes to enable functional control of a prosthetic limb. Beyond motor decoding from recording arrays, precise placement of stimulating electrodes in cortical areas associated with finger and fingertip sensations allows for the delivery of sensory feedback that could improve dexterous control of prosthetic hands. In this study, the authors demonstrated the use of a novel intraoperative online functional mapping (OFM) technique with high-density electrocorticography to localize finger representations in human primary somatosensory cortex. In conjunction with traditional pre- and intraoperative targeting approaches, this technique enabled accurate implantation of stimulating microelectrodes, which was confirmed by postimplantation intracortical stimulation of finger and fingertip sensations. This work demonstrates the utility of intraoperative OFM and will inform future studies of closed-loop BMIs in humans.

AB - Defining eloquent cortex intraoperatively, traditionally performed by neurosurgeons to preserve patient function, can now help target electrode implantation for restoring function. Brain-machine interfaces (BMIs) have the potential to restore upper-limb motor control to paralyzed patients but require accurate placement of recording and stimulating electrodes to enable functional control of a prosthetic limb. Beyond motor decoding from recording arrays, precise placement of stimulating electrodes in cortical areas associated with finger and fingertip sensations allows for the delivery of sensory feedback that could improve dexterous control of prosthetic hands. In this study, the authors demonstrated the use of a novel intraoperative online functional mapping (OFM) technique with high-density electrocorticography to localize finger representations in human primary somatosensory cortex. In conjunction with traditional pre- and intraoperative targeting approaches, this technique enabled accurate implantation of stimulating microelectrodes, which was confirmed by postimplantation intracortical stimulation of finger and fingertip sensations. This work demonstrates the utility of intraoperative OFM and will inform future studies of closed-loop BMIs in humans.

KW - brain-computer interface

KW - brain-machine interface

KW - ECoG

KW - electrocorticography

KW - epilepsy

KW - intracortical microstimulation

KW - intraoperative functional mapping

KW - MEA

KW - microelectrode array

KW - online functional mapping

KW - surgical technique

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UR - http://www.scopus.com/inward/citedby.url?scp=85194013563&partnerID=8YFLogxK

U2 - 10.3171/2020.9.JNS202675

DO - 10.3171/2020.9.JNS202675

M3 - Article

C2 - 33770760

AN - SCOPUS:85194013563

SN - 0022-3085

VL - 135

SP - 1493

EP - 1500

JO - Journal of neurosurgery

JF - Journal of neurosurgery

IS - 5

ER -

Novel intraoperative online functional mapping of somatosensory finger representations for targeted stimulating electrode placement: technical note

Abstract

Keywords

ASJC Scopus subject areas

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