Towards a Foundation Model for Cortical Folding

Julien Laval; Joël Chavas; Vanessa Troiani; William Snyder; Marisa Patti; Mylène Moyal; Marion Plaze; Arnaud Cachia; Zhong Yi Sun; Vincent Frouin; Pietro Gori; Denis Rivière; Jean François Mangin

doi:10.1007/978-3-031-78761-4_8

Towards a Foundation Model for Cortical Folding

Julien Laval
, Joël Chavas
, Vanessa Troiani
, William Snyder
, Marisa Patti
, Mylène Moyal
, Marion Plaze
, Arnaud Cachia
, Zhong Yi Sun
, Vincent Frouin
, Pietro Gori
, Denis Rivière
, Jean François Mangin

Université Paris-Saclay
Geisinger Autism and Developmental Medicine Institute
Department of Health and Human Services
Department of Psychiatry
Drexel University
Université de Paris
Université de Paris
Institut du Cerveau et de la Moelle épinière (ICM)

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

The brain surface is composed of humps called gyri, separated by grooves called sulci. Although the main folds are common to all individuals, their shape varies, making them unique to each individual. Cortical folding may contain biomarkers that have yet to be deciphered. While conventional geometric approaches fail to fully characterize the high inter-individual variability, recent efforts in large-scale MRI data collection allow us to leverage the statistical power of deep neural networks. Here, we introduce Champollion V0, a self-supervised learning (SSL) algorithm to sort sulcal variability based on 21,070 subjects from the UKBioBank dataset. We revisit from scratch an existing model and optimize its ability to retrieve hand-labeled patterns defined by the neuroscientific community. Under linear evaluation on the latent space, Champollion V0 significantly improves the detection of three different kinds of folding patterns: the presence of a parallel sulcus (AUC increases from 73% to 84%), the presence of specific interruptions (AUC increases from 50% to 79%) and the detection of a specific folding shape (R² increases on each of the six main geometric features), respectively in the cingulate, the orbital and the central region. These hand-labeled patterns were found to be correlated to neurodevelopmental pathologies. Champollion V0 could enable the automatic labeling of larger datasets for future studies. The code can be found on Github.

Original language	English
Title of host publication	Machine Learning in Clinical Neuroimaging - 7th International Workshop, MLCN 2024, Held in Conjunction with MICCAI 2024, Proceedings
Editors	Deepti R. Bathula, Anoop Benet Nirmala, Nicha C. Dvornek, Sindhuja T. Govindarajan, Mohamad Habes, Vinod Kumar, Ahmed Nebli, Thomas Wolfers, Yiming Xiao
Publisher	Springer Science and Business Media Deutschland GmbH
Pages	78-88
Number of pages	11
ISBN (Print)	9783031787607
DOIs	https://doi.org/10.1007/978-3-031-78761-4_8
Publication status	Published - 1 Jan 2025
Event	7th International Workshop on Machine Learning in Clinical Neuroimaging, MLCN 2024, Held in Conjunction with 27th International Conference on Medical Image Computing and Computer-Assisted Intervention, MICCAI 2024 - Marrakesh, Morocco Duration: 10 Oct 2024 → 10 Oct 2024

Publication series

Name	Lecture Notes in Computer Science
Volume	15266 LNCS
ISSN (Print)	0302-9743
ISSN (Electronic)	1611-3349

Conference

Conference	7th International Workshop on Machine Learning in Clinical Neuroimaging, MLCN 2024, Held in Conjunction with 27th International Conference on Medical Image Computing and Computer-Assisted Intervention, MICCAI 2024
Country/Territory	Morocco
City	Marrakesh
Period	10/10/24 → 10/10/24

Keywords

Brain
MRI
Self-supervised learning
folding patterns

Access to Document

10.1007/978-3-031-78761-4_8

Cite this

Laval, J., Chavas, J., Troiani, V., Snyder, W., Patti, M., Moyal, M., Plaze, M., Cachia, A., Yi Sun, Z., Frouin, V., Gori, P., Rivière, D., & Mangin, J. F. (2025). Towards a Foundation Model for Cortical Folding. In D. R. Bathula, A. Benet Nirmala, N. C. Dvornek, S. T. Govindarajan, M. Habes, V. Kumar, A. Nebli, T. Wolfers, & Y. Xiao (Eds.), Machine Learning in Clinical Neuroimaging - 7th International Workshop, MLCN 2024, Held in Conjunction with MICCAI 2024, Proceedings (pp. 78-88). (Lecture Notes in Computer Science; Vol. 15266 LNCS). Springer Science and Business Media Deutschland GmbH. https://doi.org/10.1007/978-3-031-78761-4_8

Laval, Julien ; Chavas, Joël ; Troiani, Vanessa et al. / Towards a Foundation Model for Cortical Folding. Machine Learning in Clinical Neuroimaging - 7th International Workshop, MLCN 2024, Held in Conjunction with MICCAI 2024, Proceedings. editor / Deepti R. Bathula ; Anoop Benet Nirmala ; Nicha C. Dvornek ; Sindhuja T. Govindarajan ; Mohamad Habes ; Vinod Kumar ; Ahmed Nebli ; Thomas Wolfers ; Yiming Xiao. Springer Science and Business Media Deutschland GmbH, 2025. pp. 78-88 (Lecture Notes in Computer Science).

@inproceedings{026321a509e144828c9726101646e95e,

title = "Towards a Foundation Model for Cortical Folding",

abstract = "The brain surface is composed of humps called gyri, separated by grooves called sulci. Although the main folds are common to all individuals, their shape varies, making them unique to each individual. Cortical folding may contain biomarkers that have yet to be deciphered. While conventional geometric approaches fail to fully characterize the high inter-individual variability, recent efforts in large-scale MRI data collection allow us to leverage the statistical power of deep neural networks. Here, we introduce Champollion V0, a self-supervised learning (SSL) algorithm to sort sulcal variability based on 21,070 subjects from the UKBioBank dataset. We revisit from scratch an existing model and optimize its ability to retrieve hand-labeled patterns defined by the neuroscientific community. Under linear evaluation on the latent space, Champollion V0 significantly improves the detection of three different kinds of folding patterns: the presence of a parallel sulcus (AUC increases from 73\% to 84\%), the presence of specific interruptions (AUC increases from 50\% to 79\%) and the detection of a specific folding shape (R2 increases on each of the six main geometric features), respectively in the cingulate, the orbital and the central region. These hand-labeled patterns were found to be correlated to neurodevelopmental pathologies. Champollion V0 could enable the automatic labeling of larger datasets for future studies. The code can be found on Github.",

keywords = "Brain, MRI, Self-supervised learning, folding patterns",

author = "Julien Laval and Jo{\"e}l Chavas and Vanessa Troiani and William Snyder and Marisa Patti and Myl{\`e}ne Moyal and Marion Plaze and Arnaud Cachia and \{Yi Sun\}, Zhong and Vincent Frouin and Pietro Gori and Denis Rivi{\`e}re and Mangin, \{Jean Fran{\c c}ois\}",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive license to Springer Nature Switzerland AG 2025.; 7th International Workshop on Machine Learning in Clinical Neuroimaging, MLCN 2024, Held in Conjunction with 27th International Conference on Medical Image Computing and Computer-Assisted Intervention, MICCAI 2024 ; Conference date: 10-10-2024 Through 10-10-2024",

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series = "Lecture Notes in Computer Science",

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pages = "78--88",

editor = "Bathula, \{Deepti R.\} and \{Benet Nirmala\}, Anoop and Dvornek, \{Nicha C.\} and Govindarajan, \{Sindhuja T.\} and Mohamad Habes and Vinod Kumar and Ahmed Nebli and Thomas Wolfers and Yiming Xiao",

booktitle = "Machine Learning in Clinical Neuroimaging - 7th International Workshop, MLCN 2024, Held in Conjunction with MICCAI 2024, Proceedings",

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Laval, J, Chavas, J, Troiani, V, Snyder, W, Patti, M, Moyal, M, Plaze, M, Cachia, A, Yi Sun, Z, Frouin, V, Gori, P, Rivière, D & Mangin, JF 2025, Towards a Foundation Model for Cortical Folding. in DR Bathula, A Benet Nirmala, NC Dvornek, ST Govindarajan, M Habes, V Kumar, A Nebli, T Wolfers & Y Xiao (eds), Machine Learning in Clinical Neuroimaging - 7th International Workshop, MLCN 2024, Held in Conjunction with MICCAI 2024, Proceedings. Lecture Notes in Computer Science, vol. 15266 LNCS, Springer Science and Business Media Deutschland GmbH, pp. 78-88, 7th International Workshop on Machine Learning in Clinical Neuroimaging, MLCN 2024, Held in Conjunction with 27th International Conference on Medical Image Computing and Computer-Assisted Intervention, MICCAI 2024, Marrakesh, Morocco, 10/10/24. https://doi.org/10.1007/978-3-031-78761-4_8

Towards a Foundation Model for Cortical Folding. / Laval, Julien; Chavas, Joël; Troiani, Vanessa et al.
Machine Learning in Clinical Neuroimaging - 7th International Workshop, MLCN 2024, Held in Conjunction with MICCAI 2024, Proceedings. ed. / Deepti R. Bathula; Anoop Benet Nirmala; Nicha C. Dvornek; Sindhuja T. Govindarajan; Mohamad Habes; Vinod Kumar; Ahmed Nebli; Thomas Wolfers; Yiming Xiao. Springer Science and Business Media Deutschland GmbH, 2025. p. 78-88 (Lecture Notes in Computer Science; Vol. 15266 LNCS).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Laval, Julien

AU - Chavas, Joël

AU - Troiani, Vanessa

AU - Snyder, William

AU - Patti, Marisa

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AU - Plaze, Marion

AU - Cachia, Arnaud

AU - Yi Sun, Zhong

AU - Frouin, Vincent

AU - Gori, Pietro

AU - Rivière, Denis

AU - Mangin, Jean François

N1 - Publisher Copyright: © The Author(s), under exclusive license to Springer Nature Switzerland AG 2025.

PY - 2025/1/1

Y1 - 2025/1/1

N2 - The brain surface is composed of humps called gyri, separated by grooves called sulci. Although the main folds are common to all individuals, their shape varies, making them unique to each individual. Cortical folding may contain biomarkers that have yet to be deciphered. While conventional geometric approaches fail to fully characterize the high inter-individual variability, recent efforts in large-scale MRI data collection allow us to leverage the statistical power of deep neural networks. Here, we introduce Champollion V0, a self-supervised learning (SSL) algorithm to sort sulcal variability based on 21,070 subjects from the UKBioBank dataset. We revisit from scratch an existing model and optimize its ability to retrieve hand-labeled patterns defined by the neuroscientific community. Under linear evaluation on the latent space, Champollion V0 significantly improves the detection of three different kinds of folding patterns: the presence of a parallel sulcus (AUC increases from 73% to 84%), the presence of specific interruptions (AUC increases from 50% to 79%) and the detection of a specific folding shape (R2 increases on each of the six main geometric features), respectively in the cingulate, the orbital and the central region. These hand-labeled patterns were found to be correlated to neurodevelopmental pathologies. Champollion V0 could enable the automatic labeling of larger datasets for future studies. The code can be found on Github.

AB - The brain surface is composed of humps called gyri, separated by grooves called sulci. Although the main folds are common to all individuals, their shape varies, making them unique to each individual. Cortical folding may contain biomarkers that have yet to be deciphered. While conventional geometric approaches fail to fully characterize the high inter-individual variability, recent efforts in large-scale MRI data collection allow us to leverage the statistical power of deep neural networks. Here, we introduce Champollion V0, a self-supervised learning (SSL) algorithm to sort sulcal variability based on 21,070 subjects from the UKBioBank dataset. We revisit from scratch an existing model and optimize its ability to retrieve hand-labeled patterns defined by the neuroscientific community. Under linear evaluation on the latent space, Champollion V0 significantly improves the detection of three different kinds of folding patterns: the presence of a parallel sulcus (AUC increases from 73% to 84%), the presence of specific interruptions (AUC increases from 50% to 79%) and the detection of a specific folding shape (R2 increases on each of the six main geometric features), respectively in the cingulate, the orbital and the central region. These hand-labeled patterns were found to be correlated to neurodevelopmental pathologies. Champollion V0 could enable the automatic labeling of larger datasets for future studies. The code can be found on Github.

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KW - MRI

KW - Self-supervised learning

KW - folding patterns

U2 - 10.1007/978-3-031-78761-4_8

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SN - 9783031787607

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BT - Machine Learning in Clinical Neuroimaging - 7th International Workshop, MLCN 2024, Held in Conjunction with MICCAI 2024, Proceedings

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A2 - Dvornek, Nicha C.

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A2 - Wolfers, Thomas

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Laval J, Chavas J, Troiani V, Snyder W, Patti M, Moyal M et al. Towards a Foundation Model for Cortical Folding. In Bathula DR, Benet Nirmala A, Dvornek NC, Govindarajan ST, Habes M, Kumar V, Nebli A, Wolfers T, Xiao Y, editors, Machine Learning in Clinical Neuroimaging - 7th International Workshop, MLCN 2024, Held in Conjunction with MICCAI 2024, Proceedings. Springer Science and Business Media Deutschland GmbH. 2025. p. 78-88. (Lecture Notes in Computer Science). doi: 10.1007/978-3-031-78761-4_8