Disuse-driven plasticity in the human thalamus and putamen

Roselyne J. Chauvin; Dillan J. Newbold; Ashley N. Nielsen; Ryland L. Miller; Samuel R. Krimmel; Athanasia Metoki; Anxu Wang; Andrew N. Van; David F. Montez; Scott Marek; Vahdeta Suljic; Noah J. Baden; Nadeshka Ramirez-Perez; Kristen M. Scheidter; Julia S. Monk; Forrest I. Whiting; Babatunde Adeyemo; Jarod L. Roland; Abraham Z. Snyder; Benjamin P. Kay; Marcus E. Raichle; Timothy O. Laumann; Evan M. Gordon; Nico U.F. Dosenbach

doi:10.1016/j.celrep.2025.115570

Disuse-driven plasticity in the human thalamus and putamen

Roselyne J. Chauvin, Dillan J. Newbold, Ashley N. Nielsen, Ryland L. Miller, Samuel R. Krimmel, Athanasia Metoki, Anxu Wang, Andrew N. Van, David F. Montez, Scott Marek, Vahdeta Suljic, Noah J. Baden, Nadeshka Ramirez-Perez, Kristen M. Scheidter, Julia S. Monk, Forrest I. Whiting, Babatunde Adeyemo, Jarod L. Roland, Abraham Z. Snyder, Benjamin P. KayMarcus E. Raichle, Timothy O. Laumann, Evan M. Gordon, Nico U.F. Dosenbach

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

Abstract

Subcortical plasticity has mainly been studied using invasive electrophysiology in animals. Here, we leverage precision functional mapping (PFM) to study motor plasticity in the human subcortex during 2 weeks of upper-extremity immobilization with daily resting-state and motor task fMRI. We found previously that, in the cortex, limb disuse drastically impacts disused primary motor cortex functional connectivity (FC) and is associated with spontaneous fMRI pulses. It remains unknown whether disuse-driven plasticity pulses and FC changes are cortex specific or whether they could also affect movement-critical nodes in the thalamus and striatum. Tailored analysis methods now show spontaneous disuse pulses and FC changes in the dorsal posterior putamen and central thalamus (centromedian [CM], ventral-intermediate [VIM], and ventroposterior-lateral nuclei), representing a motor circuit-wide plasticity phenomenon. The posterior putamen effects suggest plasticity in stimulus-driven habit circuitry. Importantly, thalamic plasticity effects are focal to nuclei used as deep brain stimulation targets for essential tremor/Parkinson's disease (VIM) and epilepsy/coma (CM).

Original language	English
Article number	115570
Journal	Cell Reports
Volume	44
Issue number	4
DOIs	https://doi.org/10.1016/j.celrep.2025.115570
State	Published - Apr 22 2025

Keywords

CP: Neuroscience
disused
fMRI
motor plasticity
putamen
resting state
thalamus

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10.1016/j.celrep.2025.115570

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Chauvin, R. J., Newbold, D. J., Nielsen, A. N., Miller, R. L., Krimmel, S. R., Metoki, A., Wang, A., Van, A. N., Montez, D. F., Marek, S., Suljic, V., Baden, N. J., Ramirez-Perez, N., Scheidter, K. M., Monk, J. S., Whiting, F. I., Adeyemo, B., Roland, J. L., Snyder, A. Z., ... Dosenbach, N. U. F. (2025). Disuse-driven plasticity in the human thalamus and putamen. Cell Reports, 44(4), Article 115570. https://doi.org/10.1016/j.celrep.2025.115570

@article{b50393fc04454c37a5203296a5caf097,

title = "Disuse-driven plasticity in the human thalamus and putamen",

abstract = "Subcortical plasticity has mainly been studied using invasive electrophysiology in animals. Here, we leverage precision functional mapping (PFM) to study motor plasticity in the human subcortex during 2 weeks of upper-extremity immobilization with daily resting-state and motor task fMRI. We found previously that, in the cortex, limb disuse drastically impacts disused primary motor cortex functional connectivity (FC) and is associated with spontaneous fMRI pulses. It remains unknown whether disuse-driven plasticity pulses and FC changes are cortex specific or whether they could also affect movement-critical nodes in the thalamus and striatum. Tailored analysis methods now show spontaneous disuse pulses and FC changes in the dorsal posterior putamen and central thalamus (centromedian [CM], ventral-intermediate [VIM], and ventroposterior-lateral nuclei), representing a motor circuit-wide plasticity phenomenon. The posterior putamen effects suggest plasticity in stimulus-driven habit circuitry. Importantly, thalamic plasticity effects are focal to nuclei used as deep brain stimulation targets for essential tremor/Parkinson's disease (VIM) and epilepsy/coma (CM).",

keywords = "CP: Neuroscience, disused, fMRI, motor plasticity, putamen, resting state, thalamus",

author = "Chauvin, {Roselyne J.} and Newbold, {Dillan J.} and Nielsen, {Ashley N.} and Miller, {Ryland L.} and Krimmel, {Samuel R.} and Athanasia Metoki and Anxu Wang and Van, {Andrew N.} and Montez, {David F.} and Scott Marek and Vahdeta Suljic and Baden, {Noah J.} and Nadeshka Ramirez-Perez and Scheidter, {Kristen M.} and Monk, {Julia S.} and Whiting, {Forrest I.} and Babatunde Adeyemo and Roland, {Jarod L.} and Snyder, {Abraham Z.} and Kay, {Benjamin P.} and Raichle, {Marcus E.} and Laumann, {Timothy O.} and Gordon, {Evan M.} and Dosenbach, {Nico U.F.}",

note = "Publisher Copyright: {\textcopyright} 2025 The Authors",

year = "2025",

month = apr,

day = "22",

doi = "10.1016/j.celrep.2025.115570",

language = "English",

volume = "44",

journal = "Cell Reports",

issn = "2639-1856",

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Chauvin, RJ, Newbold, DJ, Nielsen, AN, Miller, RL, Krimmel, SR, Metoki, A, Wang, A, Van, AN, Montez, DF, Marek, S, Suljic, V, Baden, NJ, Ramirez-Perez, N, Scheidter, KM, Monk, JS, Whiting, FI, Adeyemo, B, Roland, JL , Snyder, AZ , Kay, BP , Raichle, ME , Laumann, TO , Gordon, EM & Dosenbach, NUF 2025, 'Disuse-driven plasticity in the human thalamus and putamen', Cell Reports, vol. 44, no. 4, 115570. https://doi.org/10.1016/j.celrep.2025.115570

TY - JOUR

T1 - Disuse-driven plasticity in the human thalamus and putamen

AU - Chauvin, Roselyne J.

AU - Newbold, Dillan J.

AU - Nielsen, Ashley N.

AU - Miller, Ryland L.

AU - Krimmel, Samuel R.

AU - Metoki, Athanasia

AU - Wang, Anxu

AU - Van, Andrew N.

AU - Montez, David F.

AU - Marek, Scott

AU - Suljic, Vahdeta

AU - Baden, Noah J.

AU - Ramirez-Perez, Nadeshka

AU - Scheidter, Kristen M.

AU - Monk, Julia S.

AU - Whiting, Forrest I.

AU - Adeyemo, Babatunde

AU - Roland, Jarod L.

AU - Snyder, Abraham Z.

AU - Kay, Benjamin P.

AU - Raichle, Marcus E.

AU - Laumann, Timothy O.

AU - Gordon, Evan M.

AU - Dosenbach, Nico U.F.

PY - 2025/4/22

Y1 - 2025/4/22

N2 - Subcortical plasticity has mainly been studied using invasive electrophysiology in animals. Here, we leverage precision functional mapping (PFM) to study motor plasticity in the human subcortex during 2 weeks of upper-extremity immobilization with daily resting-state and motor task fMRI. We found previously that, in the cortex, limb disuse drastically impacts disused primary motor cortex functional connectivity (FC) and is associated with spontaneous fMRI pulses. It remains unknown whether disuse-driven plasticity pulses and FC changes are cortex specific or whether they could also affect movement-critical nodes in the thalamus and striatum. Tailored analysis methods now show spontaneous disuse pulses and FC changes in the dorsal posterior putamen and central thalamus (centromedian [CM], ventral-intermediate [VIM], and ventroposterior-lateral nuclei), representing a motor circuit-wide plasticity phenomenon. The posterior putamen effects suggest plasticity in stimulus-driven habit circuitry. Importantly, thalamic plasticity effects are focal to nuclei used as deep brain stimulation targets for essential tremor/Parkinson's disease (VIM) and epilepsy/coma (CM).

AB - Subcortical plasticity has mainly been studied using invasive electrophysiology in animals. Here, we leverage precision functional mapping (PFM) to study motor plasticity in the human subcortex during 2 weeks of upper-extremity immobilization with daily resting-state and motor task fMRI. We found previously that, in the cortex, limb disuse drastically impacts disused primary motor cortex functional connectivity (FC) and is associated with spontaneous fMRI pulses. It remains unknown whether disuse-driven plasticity pulses and FC changes are cortex specific or whether they could also affect movement-critical nodes in the thalamus and striatum. Tailored analysis methods now show spontaneous disuse pulses and FC changes in the dorsal posterior putamen and central thalamus (centromedian [CM], ventral-intermediate [VIM], and ventroposterior-lateral nuclei), representing a motor circuit-wide plasticity phenomenon. The posterior putamen effects suggest plasticity in stimulus-driven habit circuitry. Importantly, thalamic plasticity effects are focal to nuclei used as deep brain stimulation targets for essential tremor/Parkinson's disease (VIM) and epilepsy/coma (CM).

KW - CP: Neuroscience

KW - disused

KW - fMRI

KW - motor plasticity

KW - putamen

KW - resting state

KW - thalamus

UR - http://www.scopus.com/inward/record.url?scp=105002243359&partnerID=8YFLogxK

U2 - 10.1016/j.celrep.2025.115570

DO - 10.1016/j.celrep.2025.115570

M3 - Article

C2 - 40220292

AN - SCOPUS:105002243359

SN - 2639-1856

VL - 44

JO - Cell Reports

JF - Cell Reports

IS - 4

M1 - 115570

ER -

Disuse-driven plasticity in the human thalamus and putamen

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