Spike-phase coupling of subthalamic neurons to posterior perisylvian cortex predicts speech sound accuracy

Matteo Vissani; Alan Bush; Witold J. Lipski; Latané Bullock; Petra Fischer; Clemens Neudorfer; Lori L. Holt; Julie A. Fiez; Robert S. Turner; R. Mark Richardson

doi:10.1038/s41467-025-58781-8

Spike-phase coupling of subthalamic neurons to posterior perisylvian cortex predicts speech sound accuracy

Matteo Vissani^*, Alan Bush, Witold J. Lipski, Latané Bullock, Petra Fischer, Clemens Neudorfer, Lori L. Holt, Julie A. Fiez, Robert S. Turner, R. Mark Richardson^*

^*Corresponding author for this work

Research output: Contribution to journal › Article (Academic Journal) › peer-review

Abstract

Speech provides a rich context for understanding how cortical interactions with the basal ganglia contribute to unique human behaviors, but opportunities for direct human intracranial recordings across cortical-basal ganglia networks are rare. Here we have recorded electrocorticographic signals in the cortex synchronously with single units in the basal ganglia during awake neurosurgeries where participants spoke syllable repetitions. We have discovered that individual subthalamic nucleus (STN) neurons have transient (200 ms) spike-phase coupling (SPC) events with multiple cortical regions. The spike timing of STN neurons is locked to the phase of theta-alpha oscillations in the supramarginal and posterior superior temporal gyrus during speech planning and production. Speech sound errors occur when this STN-cortical interaction is delayed. Our results suggest that timely interactions between the STN and the posterior perisylvian cortex support auditory-motor coordinate transformation or phonological working memory during speech planning. These findings establish a framework for understanding cortical-basal ganglia interaction in other human behaviors, and additionally indicate that firing-rate based models are insufficient for explaining basal ganglia circuit behavior.

Original language	English
Article number	3357
Number of pages	20
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-58781-8
Publication status	Published - 9 Apr 2025

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@article{f92dd9687d584facbfaf73ecbffb6151,

title = "Spike-phase coupling of subthalamic neurons to posterior perisylvian cortex predicts speech sound accuracy",

abstract = "Speech provides a rich context for understanding how cortical interactions with the basal ganglia contribute to unique human behaviors, but opportunities for direct human intracranial recordings across cortical-basal ganglia networks are rare. Here we have recorded electrocorticographic signals in the cortex synchronously with single units in the basal ganglia during awake neurosurgeries where participants spoke syllable repetitions. We have discovered that individual subthalamic nucleus (STN) neurons have transient (200 ms) spike-phase coupling (SPC) events with multiple cortical regions. The spike timing of STN neurons is locked to the phase of theta-alpha oscillations in the supramarginal and posterior superior temporal gyrus during speech planning and production. Speech sound errors occur when this STN-cortical interaction is delayed. Our results suggest that timely interactions between the STN and the posterior perisylvian cortex support auditory-motor coordinate transformation or phonological working memory during speech planning. These findings establish a framework for understanding cortical-basal ganglia interaction in other human behaviors, and additionally indicate that firing-rate based models are insufficient for explaining basal ganglia circuit behavior.",

author = "Matteo Vissani and Alan Bush and Lipski, {Witold J.} and Latan{\'e} Bullock and Petra Fischer and Clemens Neudorfer and Holt, {Lori L.} and Fiez, {Julie A.} and Turner, {Robert S.} and Richardson, {R. Mark}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

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doi = "10.1038/s41467-025-58781-8",

language = "English",

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TY - JOUR

T1 - Spike-phase coupling of subthalamic neurons to posterior perisylvian cortex predicts speech sound accuracy

AU - Vissani, Matteo

AU - Bush, Alan

AU - Lipski, Witold J.

AU - Bullock, Latané

AU - Fischer, Petra

AU - Neudorfer, Clemens

AU - Holt, Lori L.

AU - Fiez, Julie A.

AU - Turner, Robert S.

AU - Richardson, R. Mark

PY - 2025/4/9

Y1 - 2025/4/9

N2 - Speech provides a rich context for understanding how cortical interactions with the basal ganglia contribute to unique human behaviors, but opportunities for direct human intracranial recordings across cortical-basal ganglia networks are rare. Here we have recorded electrocorticographic signals in the cortex synchronously with single units in the basal ganglia during awake neurosurgeries where participants spoke syllable repetitions. We have discovered that individual subthalamic nucleus (STN) neurons have transient (200 ms) spike-phase coupling (SPC) events with multiple cortical regions. The spike timing of STN neurons is locked to the phase of theta-alpha oscillations in the supramarginal and posterior superior temporal gyrus during speech planning and production. Speech sound errors occur when this STN-cortical interaction is delayed. Our results suggest that timely interactions between the STN and the posterior perisylvian cortex support auditory-motor coordinate transformation or phonological working memory during speech planning. These findings establish a framework for understanding cortical-basal ganglia interaction in other human behaviors, and additionally indicate that firing-rate based models are insufficient for explaining basal ganglia circuit behavior.

AB - Speech provides a rich context for understanding how cortical interactions with the basal ganglia contribute to unique human behaviors, but opportunities for direct human intracranial recordings across cortical-basal ganglia networks are rare. Here we have recorded electrocorticographic signals in the cortex synchronously with single units in the basal ganglia during awake neurosurgeries where participants spoke syllable repetitions. We have discovered that individual subthalamic nucleus (STN) neurons have transient (200 ms) spike-phase coupling (SPC) events with multiple cortical regions. The spike timing of STN neurons is locked to the phase of theta-alpha oscillations in the supramarginal and posterior superior temporal gyrus during speech planning and production. Speech sound errors occur when this STN-cortical interaction is delayed. Our results suggest that timely interactions between the STN and the posterior perisylvian cortex support auditory-motor coordinate transformation or phonological working memory during speech planning. These findings establish a framework for understanding cortical-basal ganglia interaction in other human behaviors, and additionally indicate that firing-rate based models are insufficient for explaining basal ganglia circuit behavior.

U2 - 10.1038/s41467-025-58781-8

DO - 10.1038/s41467-025-58781-8

M3 - Article (Academic Journal)

C2 - 40204804

SN - 2041-1723

VL - 16

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 3357

ER -

Spike-phase coupling of subthalamic neurons to posterior perisylvian cortex predicts speech sound accuracy

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