Functional control of electrophysiological network architecture using direct neurostimulation in humans

Ankit N. Khambhati; Ari E. Kahn; Julia Costantini; Youssef Ezzyat; Ethan A. Solomon; Robert E. Gross; Barbara C. Jobst; Sameer A. Sheth; Kareem A. Zaghloul; Gregory Worrell; Sarah Seger; Bradley C. Lega; Shennan Weiss; Michael R. Sperling; Richard Gorniak; Sandhitsu R. Das; Joel M. Stein; Daniel S. Rizzuto; Michael J. Kahana; Timothy H. Lucas; Kathryn A. Davis; Joseph I. Tracy; Danielle S. Bassett

doi:10.1162/netn_a_00089

Functional control of electrophysiological network architecture using direct neurostimulation in humans

Ankit N. Khambhati, Ari E. Kahn, Julia Costantini, Youssef Ezzyat, Ethan A. Solomon, Robert E. Gross, Barbara C. Jobst, Sameer A. Sheth, Kareem A. Zaghloul, Gregory Worrell, Sarah Seger, Bradley C. Lega, Shennan Weiss, Michael R. Sperling, Richard Gorniak, Sandhitsu R. Das, Joel M. Stein, Daniel S. Rizzuto, Michael J. Kahana, Timothy H. LucasKathryn A. Davis, Joseph I. Tracy, Danielle S. Bassett

Neurology

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

16 Scopus citations

Abstract

Chronically implantable neurostimulation devices are becoming a clinically viable option for treating patients with neurological disease and psychiatric disorders. Neurostimulation offers the ability to probe and manipulate distributed networks of interacting brain areas in dysfunctional circuits. Here, we use tools from network control theory to examine the dynamic reconfiguration of functionally interacting neuronal ensembles during targeted neurostimulation of cortical and subcortical brain structures. By integrating multimodal intracranial recordings and diffusion-weighted imaging from patients with drug-resistant epilepsy, we test hypothesized structural and functional rules that predict altered patterns of synchronized local field potentials. We demonstrate the ability to predictably reconfigure functional interactions depending on stimulation strength and location. Stimulation of areas with structurally weak connections largely modulates the functional hubness of downstream areas and concurrently propels the brain towards more difficult-to-reach dynamical states. By using focal perturbations to bridge large-scale structure, function, and markers of behavior, our findings suggest that stimulation may be tuned to influence different scales of network interactions driving cognition.

Original language	English (US)
Pages (from-to)	848-877
Number of pages	30
Journal	Network Neuroscience
Volume	3
Issue number	3
DOIs	https://doi.org/10.1162/netn_a_00089
State	Published - Jan 1 2019

Keywords

Electrocorticography
Neurostimulation
Reconfiguration
Structural controllability

ASJC Scopus subject areas

General Neuroscience
Computer Science Applications
Artificial Intelligence
Applied Mathematics

Access to Document

10.1162/netn_a_00089

Cite this

Khambhati, A. N., Kahn, A. E., Costantini, J., Ezzyat, Y., Solomon, E. A., Gross, R. E., Jobst, B. C., Sheth, S. A., Zaghloul, K. A., Worrell, G., Seger, S., Lega, B. C., Weiss, S., Sperling, M. R., Gorniak, R., Das, S. R., Stein, J. M., Rizzuto, D. S., Kahana, M. J., ... Bassett, D. S. (2019). Functional control of electrophysiological network architecture using direct neurostimulation in humans. Network Neuroscience, 3(3), 848-877. https://doi.org/10.1162/netn_a_00089

Khambhati, AN, Kahn, AE, Costantini, J, Ezzyat, Y, Solomon, EA, Gross, RE, Jobst, BC, Sheth, SA, Zaghloul, KA, Worrell, G, Seger, S, Lega, BC, Weiss, S, Sperling, MR, Gorniak, R, Das, SR, Stein, JM, Rizzuto, DS, Kahana, MJ, Lucas, TH, Davis, KA, Tracy, JI & Bassett, DS 2019, 'Functional control of electrophysiological network architecture using direct neurostimulation in humans', Network Neuroscience, vol. 3, no. 3, pp. 848-877. https://doi.org/10.1162/netn_a_00089

@article{940354b679ec4dbebe3d779f40c1a714,

title = "Functional control of electrophysiological network architecture using direct neurostimulation in humans",

abstract = "Chronically implantable neurostimulation devices are becoming a clinically viable option for treating patients with neurological disease and psychiatric disorders. Neurostimulation offers the ability to probe and manipulate distributed networks of interacting brain areas in dysfunctional circuits. Here, we use tools from network control theory to examine the dynamic reconfiguration of functionally interacting neuronal ensembles during targeted neurostimulation of cortical and subcortical brain structures. By integrating multimodal intracranial recordings and diffusion-weighted imaging from patients with drug-resistant epilepsy, we test hypothesized structural and functional rules that predict altered patterns of synchronized local field potentials. We demonstrate the ability to predictably reconfigure functional interactions depending on stimulation strength and location. Stimulation of areas with structurally weak connections largely modulates the functional hubness of downstream areas and concurrently propels the brain towards more difficult-to-reach dynamical states. By using focal perturbations to bridge large-scale structure, function, and markers of behavior, our findings suggest that stimulation may be tuned to influence different scales of network interactions driving cognition.",

keywords = "Electrocorticography, Neurostimulation, Reconfiguration, Structural controllability",

author = "Khambhati, {Ankit N.} and Kahn, {Ari E.} and Julia Costantini and Youssef Ezzyat and Solomon, {Ethan A.} and Gross, {Robert E.} and Jobst, {Barbara C.} and Sheth, {Sameer A.} and Zaghloul, {Kareem A.} and Gregory Worrell and Sarah Seger and Lega, {Bradley C.} and Shennan Weiss and Sperling, {Michael R.} and Richard Gorniak and Das, {Sandhitsu R.} and Stein, {Joel M.} and Rizzuto, {Daniel S.} and Kahana, {Michael J.} and Lucas, {Timothy H.} and Davis, {Kathryn A.} and Tracy, {Joseph I.} and Bassett, {Danielle S.}",

note = "Publisher Copyright: {\textcopyright} 2019 Massachusetts Institute of Technology.",

year = "2019",

month = jan,

day = "1",

doi = "10.1162/netn_a_00089",

language = "English (US)",

volume = "3",

pages = "848--877",

journal = "Network Neuroscience",

issn = "2472-1751",

publisher = "MIT Press Journals",

number = "3",

}

TY - JOUR

T1 - Functional control of electrophysiological network architecture using direct neurostimulation in humans

AU - Khambhati, Ankit N.

AU - Kahn, Ari E.

AU - Costantini, Julia

AU - Ezzyat, Youssef

AU - Solomon, Ethan A.

AU - Gross, Robert E.

AU - Jobst, Barbara C.

AU - Sheth, Sameer A.

AU - Zaghloul, Kareem A.

AU - Worrell, Gregory

AU - Seger, Sarah

AU - Lega, Bradley C.

AU - Weiss, Shennan

AU - Sperling, Michael R.

AU - Gorniak, Richard

AU - Das, Sandhitsu R.

AU - Stein, Joel M.

AU - Rizzuto, Daniel S.

AU - Kahana, Michael J.

AU - Lucas, Timothy H.

AU - Davis, Kathryn A.

AU - Tracy, Joseph I.

AU - Bassett, Danielle S.

PY - 2019/1/1

Y1 - 2019/1/1

N2 - Chronically implantable neurostimulation devices are becoming a clinically viable option for treating patients with neurological disease and psychiatric disorders. Neurostimulation offers the ability to probe and manipulate distributed networks of interacting brain areas in dysfunctional circuits. Here, we use tools from network control theory to examine the dynamic reconfiguration of functionally interacting neuronal ensembles during targeted neurostimulation of cortical and subcortical brain structures. By integrating multimodal intracranial recordings and diffusion-weighted imaging from patients with drug-resistant epilepsy, we test hypothesized structural and functional rules that predict altered patterns of synchronized local field potentials. We demonstrate the ability to predictably reconfigure functional interactions depending on stimulation strength and location. Stimulation of areas with structurally weak connections largely modulates the functional hubness of downstream areas and concurrently propels the brain towards more difficult-to-reach dynamical states. By using focal perturbations to bridge large-scale structure, function, and markers of behavior, our findings suggest that stimulation may be tuned to influence different scales of network interactions driving cognition.

AB - Chronically implantable neurostimulation devices are becoming a clinically viable option for treating patients with neurological disease and psychiatric disorders. Neurostimulation offers the ability to probe and manipulate distributed networks of interacting brain areas in dysfunctional circuits. Here, we use tools from network control theory to examine the dynamic reconfiguration of functionally interacting neuronal ensembles during targeted neurostimulation of cortical and subcortical brain structures. By integrating multimodal intracranial recordings and diffusion-weighted imaging from patients with drug-resistant epilepsy, we test hypothesized structural and functional rules that predict altered patterns of synchronized local field potentials. We demonstrate the ability to predictably reconfigure functional interactions depending on stimulation strength and location. Stimulation of areas with structurally weak connections largely modulates the functional hubness of downstream areas and concurrently propels the brain towards more difficult-to-reach dynamical states. By using focal perturbations to bridge large-scale structure, function, and markers of behavior, our findings suggest that stimulation may be tuned to influence different scales of network interactions driving cognition.

KW - Electrocorticography

KW - Neurostimulation

KW - Reconfiguration

KW - Structural controllability

UR - http://www.scopus.com/inward/record.url?scp=85076354911&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=85076354911&partnerID=8YFLogxK

U2 - 10.1162/netn_a_00089

DO - 10.1162/netn_a_00089

M3 - Article

AN - SCOPUS:85076354911

SN - 2472-1751

VL - 3

SP - 848

EP - 877

JO - Network Neuroscience

JF - Network Neuroscience

IS - 3

ER -

Functional control of electrophysiological network architecture using direct neurostimulation in humans

Abstract

Keywords

ASJC Scopus subject areas

Access to Document

Other files and links

Fingerprint

Cite this