White matter connections within the central sulcus subserving the somato-cognitive action network

Georgios P. Skandalakis; Luca Viganò; Clemens Neudorfer; Marco Rossi; Luca Fornia; Gabriella Cerri; Kelsey P. Kinsman; Zabiullah Bajouri; Armin D. Tavakkoli; Christos Koutsarnakis; Evgenia Lani; Spyridon Komaitis; George Stranjalis; Gelareh Zadeh; Jessica Barrios-Martinez; Fang Cheng Yeh; Demitre Serletis; Michael Kogan; Constantinos G. Hadjipanayis; Jennifer Hong; Nathan Simmons; Evan M. Gordon; Nico U.F. Dosenbach; Andreas Horn; Lorenzo Bello; Aristotelis Kalyvas; Linton T. Evans

doi:10.1093/brain/awaf022

White matter connections within the central sulcus subserving the somato-cognitive action network

Georgios P. Skandalakis
, Luca Viganò
, Clemens Neudorfer
, Marco Rossi
, Luca Fornia
, Gabriella Cerri
, Kelsey P. Kinsman
, Zabiullah Bajouri
, Armin D. Tavakkoli
, Christos Koutsarnakis
, Evgenia Lani
, Spyridon Komaitis
, George Stranjalis
, Gelareh Zadeh
, Jessica Barrios-Martinez
, Fang Cheng Yeh
, Demitre Serletis
, Michael Kogan
, Constantinos G. Hadjipanayis
, Jennifer Hong

Nathan Simmons, Evan M. Gordon, Nico U.F. Dosenbach, Andreas Horn, Lorenzo Bello, Aristotelis Kalyvas, Linton T. Evans

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

7 Scopus citations

Abstract

The somato-cognitive action network (SCAN) consists of three nodes interspersed within Penfield's motor effector regions. The configuration of the somato-cognitive action network nodes resembles the one of the 'plis de passage' of the central sulcus: small gyri bridging the precentral and postcentral gyri. Thus, we hypothesize that these may provide a structural substrate of the somato-cognitive action network. Using microdissections of 16 human hemispheres, we consistently identified a chain of three distinct plis de passage with increased underlying white matter in locations analogous to the somato-cognitive action network nodes. We mapped localizations of plis de passage into standard stereotactic space to seed functional MRI connectivity across 9000 resting-state functional MRI scans, which demonstrated the connectivity of these sites with the somato-cognitive action network. Intraoperative recordings during direct electrical central sulcus stimulation further identified inter-effector regions corresponding to plis de passage locations. This work provides a critical step towards an improved understanding of the somato-cognitive action network in both structural and functional terms. Furthermore, our work has the potential to guide the development of refined motor cortex stimulation techniques for treating brain disorders and operative resective techniques for complex surgery of the motor cortex.

Original language	English
Pages (from-to)	1789-1800
Number of pages	12
Journal	Brain
Volume	148
Issue number	5
DOIs	https://doi.org/10.1093/brain/awaf022
State	Published - May 1 2025

Keywords

SCAN
motor cortex
plis de passage
somato-cognitive action network
white matter connectivity

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10.1093/brain/awaf022

Cite this

Skandalakis, G. P., Viganò, L., Neudorfer, C., Rossi, M., Fornia, L., Cerri, G., Kinsman, K. P., Bajouri, Z., Tavakkoli, A. D., Koutsarnakis, C., Lani, E., Komaitis, S., Stranjalis, G., Zadeh, G., Barrios-Martinez, J., Yeh, F. C., Serletis, D., Kogan, M., Hadjipanayis, C. G., ... Evans, L. T. (2025). White matter connections within the central sulcus subserving the somato-cognitive action network. Brain, 148(5), 1789-1800. https://doi.org/10.1093/brain/awaf022

@article{edd813e420ae4c1e891e4c328dea8be0,

title = "White matter connections within the central sulcus subserving the somato-cognitive action network",

abstract = "The somato-cognitive action network (SCAN) consists of three nodes interspersed within Penfield's motor effector regions. The configuration of the somato-cognitive action network nodes resembles the one of the 'plis de passage' of the central sulcus: small gyri bridging the precentral and postcentral gyri. Thus, we hypothesize that these may provide a structural substrate of the somato-cognitive action network. Using microdissections of 16 human hemispheres, we consistently identified a chain of three distinct plis de passage with increased underlying white matter in locations analogous to the somato-cognitive action network nodes. We mapped localizations of plis de passage into standard stereotactic space to seed functional MRI connectivity across 9000 resting-state functional MRI scans, which demonstrated the connectivity of these sites with the somato-cognitive action network. Intraoperative recordings during direct electrical central sulcus stimulation further identified inter-effector regions corresponding to plis de passage locations. This work provides a critical step towards an improved understanding of the somato-cognitive action network in both structural and functional terms. Furthermore, our work has the potential to guide the development of refined motor cortex stimulation techniques for treating brain disorders and operative resective techniques for complex surgery of the motor cortex.",

keywords = "SCAN, motor cortex, plis de passage, somato-cognitive action network, white matter connectivity",

author = "Skandalakis, \{Georgios P.\} and Luca Vigan{\`o} and Clemens Neudorfer and Marco Rossi and Luca Fornia and Gabriella Cerri and Kinsman, \{Kelsey P.\} and Zabiullah Bajouri and Tavakkoli, \{Armin D.\} and Christos Koutsarnakis and Evgenia Lani and Spyridon Komaitis and George Stranjalis and Gelareh Zadeh and Jessica Barrios-Martinez and Yeh, \{Fang Cheng\} and Demitre Serletis and Michael Kogan and Hadjipanayis, \{Constantinos G.\} and Jennifer Hong and Nathan Simmons and Gordon, \{Evan M.\} and Dosenbach, \{Nico U.F.\} and Andreas Horn and Lorenzo Bello and Aristotelis Kalyvas and Evans, \{Linton T.\}",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Published by Oxford University Press on behalf of the Guarantors of Brain.",

year = "2025",

month = may,

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doi = "10.1093/brain/awaf022",

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Skandalakis, GP, Viganò, L, Neudorfer, C, Rossi, M, Fornia, L, Cerri, G, Kinsman, KP, Bajouri, Z, Tavakkoli, AD, Koutsarnakis, C, Lani, E, Komaitis, S, Stranjalis, G, Zadeh, G, Barrios-Martinez, J, Yeh, FC, Serletis, D, Kogan, M, Hadjipanayis, CG, Hong, J, Simmons, N, Gordon, EM , Dosenbach, NUF, Horn, A, Bello, L, Kalyvas, A & Evans, LT 2025, 'White matter connections within the central sulcus subserving the somato-cognitive action network', Brain, vol. 148, no. 5, pp. 1789-1800. https://doi.org/10.1093/brain/awaf022

TY - JOUR

T1 - White matter connections within the central sulcus subserving the somato-cognitive action network

AU - Skandalakis, Georgios P.

AU - Viganò, Luca

AU - Neudorfer, Clemens

AU - Rossi, Marco

AU - Fornia, Luca

AU - Cerri, Gabriella

AU - Kinsman, Kelsey P.

AU - Bajouri, Zabiullah

AU - Tavakkoli, Armin D.

AU - Koutsarnakis, Christos

AU - Lani, Evgenia

AU - Komaitis, Spyridon

AU - Stranjalis, George

AU - Zadeh, Gelareh

AU - Barrios-Martinez, Jessica

AU - Yeh, Fang Cheng

AU - Serletis, Demitre

AU - Kogan, Michael

AU - Hadjipanayis, Constantinos G.

AU - Hong, Jennifer

AU - Simmons, Nathan

AU - Gordon, Evan M.

AU - Dosenbach, Nico U.F.

AU - Horn, Andreas

AU - Bello, Lorenzo

AU - Kalyvas, Aristotelis

AU - Evans, Linton T.

PY - 2025/5/1

Y1 - 2025/5/1

N2 - The somato-cognitive action network (SCAN) consists of three nodes interspersed within Penfield's motor effector regions. The configuration of the somato-cognitive action network nodes resembles the one of the 'plis de passage' of the central sulcus: small gyri bridging the precentral and postcentral gyri. Thus, we hypothesize that these may provide a structural substrate of the somato-cognitive action network. Using microdissections of 16 human hemispheres, we consistently identified a chain of three distinct plis de passage with increased underlying white matter in locations analogous to the somato-cognitive action network nodes. We mapped localizations of plis de passage into standard stereotactic space to seed functional MRI connectivity across 9000 resting-state functional MRI scans, which demonstrated the connectivity of these sites with the somato-cognitive action network. Intraoperative recordings during direct electrical central sulcus stimulation further identified inter-effector regions corresponding to plis de passage locations. This work provides a critical step towards an improved understanding of the somato-cognitive action network in both structural and functional terms. Furthermore, our work has the potential to guide the development of refined motor cortex stimulation techniques for treating brain disorders and operative resective techniques for complex surgery of the motor cortex.

AB - The somato-cognitive action network (SCAN) consists of three nodes interspersed within Penfield's motor effector regions. The configuration of the somato-cognitive action network nodes resembles the one of the 'plis de passage' of the central sulcus: small gyri bridging the precentral and postcentral gyri. Thus, we hypothesize that these may provide a structural substrate of the somato-cognitive action network. Using microdissections of 16 human hemispheres, we consistently identified a chain of three distinct plis de passage with increased underlying white matter in locations analogous to the somato-cognitive action network nodes. We mapped localizations of plis de passage into standard stereotactic space to seed functional MRI connectivity across 9000 resting-state functional MRI scans, which demonstrated the connectivity of these sites with the somato-cognitive action network. Intraoperative recordings during direct electrical central sulcus stimulation further identified inter-effector regions corresponding to plis de passage locations. This work provides a critical step towards an improved understanding of the somato-cognitive action network in both structural and functional terms. Furthermore, our work has the potential to guide the development of refined motor cortex stimulation techniques for treating brain disorders and operative resective techniques for complex surgery of the motor cortex.

KW - SCAN

KW - motor cortex

KW - plis de passage

KW - somato-cognitive action network

KW - white matter connectivity

UR - https://www.scopus.com/pages/publications/105005187304

U2 - 10.1093/brain/awaf022

DO - 10.1093/brain/awaf022

M3 - Article

C2 - 39869456

AN - SCOPUS:105005187304

SN - 0006-8950

VL - 148

SP - 1789

EP - 1800

JO - Brain

JF - Brain

IS - 5

ER -

White matter connections within the central sulcus subserving the somato-cognitive action network

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Keywords

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