End-to-End Cortical Surface Reconstruction from Clinical Magnetic Resonance Images

Jesper Duemose Nielsen; Karthik Gopinath; Andrew Hoopes; Adrian Dalca; Colin Magdamo; Steven Arnold; Sudeshna Das; Axel Thielscher; Juan Eugenio Iglesias; Oula Puonti

doi:10.1007/978-3-032-09513-8_21

End-to-End Cortical Surface Reconstruction from Clinical Magnetic Resonance Images

Jesper Duemose Nielsen^*, Karthik Gopinath, Andrew Hoopes, Adrian Dalca, Colin Magdamo, Steven Arnold, Sudeshna Das, Axel Thielscher, Juan Eugenio Iglesias, Oula Puonti

^*Corresponding author af dette arbejde

Abstract

Surface-based cortical analysis is valuable for a variety of neuroimaging tasks, such as spatial normalization, parcellation, and gray matter (GM) thickness estimation. However, most tools for estimating cortical surfaces work exclusively on scans with at least 1 mm isotropic resolution and are tuned to a specific magnetic resonance (MR) contrast, often T1-weighted (T1w). This precludes application using most clinical MR scans, which are very heterogeneous in terms of contrast and resolution. Here, we use synthetic domain-randomized data to train the first neural network for explicit estimation of cortical surfaces from scans of any contrast and resolution, without retraining. Our method deforms a template mesh to the white matter (WM) surface, which guarantees topological correctness. This mesh is further deformed to estimate the GM surface. We compare our method to recon-all-clinical (RAC), an implicit surface reconstruction method which is currently the only other tool capable of processing heterogeneous clinical MR scans, on ADNI and a large clinical dataset (n = 1,332). We show a ∼50% reduction in cortical thickness error (from 0.50 to 0.24 mm) with respect to RAC and better recovery of the aging-related cortical thinning patterns detected by FreeSurfer on high-resolution T1w scans. Our method enables fast and accurate surface reconstruction of clinical scans, allowing studies (1) with sample sizes far beyond what is feasible in a research setting, and (2) of clinical populations that are difficult to enroll in research studies. The code is publicly available at https://github.com/simnibs/brainnet.

Originalsprog	Engelsk
Titel	Machine Learning in Medical Imaging - 16th International Workshop, MLMI 2025, Held in Conjunction with MICCAI 2025, Proceedings
Redaktører	Zhiming Cui, Islem Rekik, Heung-IL Suk, Xi Ouyang, Kaicong Sun, Sheng Wang
Antal sider	12
Forlag	Springer
Publikationsdato	2026
Sider	212-223
ISBN (Trykt)	9783032095121
DOI	https://doi.org/10.1007/978-3-032-09513-8_21
Status	Udgivet - 2026
Begivenhed	16th International Workshop on Machine Learning in Medical Imaging, MLMI 2025 was held in conjunction with the 28th International Conference on Medical Image Computing and Computer Assisted Intervention, MICCAI 2025 - Daejeon, Sydkorea Varighed: 23 sep. 2025 → 23 sep. 2025

Konference

Konference	16th International Workshop on Machine Learning in Medical Imaging, MLMI 2025 was held in conjunction with the 28th International Conference on Medical Image Computing and Computer Assisted Intervention, MICCAI 2025
Land/Område	Sydkorea
By	Daejeon
Periode	23/09/2025 → 23/09/2025

Navn	Lecture Notes in Computer Science
Vol/bind	16241
ISSN	0302-9743

Adgang til dokumentet

10.1007/978-3-032-09513-8_21

Andre filer og links

Link to publication in Scopus

Citationsformater

Nielsen, J. D., Gopinath, K., Hoopes, A., Dalca, A., Magdamo, C., Arnold, S., Das, S., Thielscher, A., Iglesias, J. E., & Puonti, O. (2026). End-to-End Cortical Surface Reconstruction from Clinical Magnetic Resonance Images. I Z. Cui, I. Rekik, H.-IL. Suk, X. Ouyang, K. Sun, & S. Wang (red.), Machine Learning in Medical Imaging - 16th International Workshop, MLMI 2025, Held in Conjunction with MICCAI 2025, Proceedings (s. 212-223). Springer. https://doi.org/10.1007/978-3-032-09513-8_21

End-to-End Cortical Surface Reconstruction from Clinical Magnetic Resonance Images. / Nielsen, Jesper Duemose; Gopinath, Karthik; Hoopes, Andrew et al.
Machine Learning in Medical Imaging - 16th International Workshop, MLMI 2025, Held in Conjunction with MICCAI 2025, Proceedings. red. / Zhiming Cui; Islem Rekik; Heung-IL Suk; Xi Ouyang; Kaicong Sun; Sheng Wang. Springer, 2026. s. 212-223 (Lecture Notes in Computer Science, Bind 16241).

Publikation: Bidrag til bog/antologi/rapport › Konferencebidrag i proceedings › Forskning › peer review

Nielsen, JD, Gopinath, K, Hoopes, A, Dalca, A, Magdamo, C, Arnold, S, Das, S, Thielscher, A, Iglesias, JE & Puonti, O 2026, End-to-End Cortical Surface Reconstruction from Clinical Magnetic Resonance Images. i Z Cui, I Rekik, H-IL Suk, X Ouyang, K Sun & S Wang (red), Machine Learning in Medical Imaging - 16th International Workshop, MLMI 2025, Held in Conjunction with MICCAI 2025, Proceedings. Springer, Lecture Notes in Computer Science, bind 16241, s. 212-223, 16th International Workshop on Machine Learning in Medical Imaging, MLMI 2025 was held in conjunction with the 28th International Conference on Medical Image Computing and Computer Assisted Intervention, MICCAI 2025, Daejeon, Sydkorea, 23/09/2025. https://doi.org/10.1007/978-3-032-09513-8_21

Nielsen JD, Gopinath K, Hoopes A, Dalca A, Magdamo C, Arnold S et al. End-to-End Cortical Surface Reconstruction from Clinical Magnetic Resonance Images. I Cui Z, Rekik I, Suk HIL, Ouyang X, Sun K, Wang S, red., Machine Learning in Medical Imaging - 16th International Workshop, MLMI 2025, Held in Conjunction with MICCAI 2025, Proceedings. Springer. 2026. s. 212-223. (Lecture Notes in Computer Science, Bind 16241). doi: 10.1007/978-3-032-09513-8_21

Nielsen, Jesper Duemose ; Gopinath, Karthik ; Hoopes, Andrew et al. / End-to-End Cortical Surface Reconstruction from Clinical Magnetic Resonance Images. Machine Learning in Medical Imaging - 16th International Workshop, MLMI 2025, Held in Conjunction with MICCAI 2025, Proceedings. red. / Zhiming Cui ; Islem Rekik ; Heung-IL Suk ; Xi Ouyang ; Kaicong Sun ; Sheng Wang. Springer, 2026. s. 212-223 (Lecture Notes in Computer Science, Bind 16241).

@inproceedings{d99ffd1e09104c98ae5869192177f5c4,

title = "End-to-End Cortical Surface Reconstruction from Clinical Magnetic Resonance Images",

abstract = "Surface-based cortical analysis is valuable for a variety of neuroimaging tasks, such as spatial normalization, parcellation, and gray matter (GM) thickness estimation. However, most tools for estimating cortical surfaces work exclusively on scans with at least 1 mm isotropic resolution and are tuned to a specific magnetic resonance (MR) contrast, often T1-weighted (T1w). This precludes application using most clinical MR scans, which are very heterogeneous in terms of contrast and resolution. Here, we use synthetic domain-randomized data to train the first neural network for explicit estimation of cortical surfaces from scans of any contrast and resolution, without retraining. Our method deforms a template mesh to the white matter (WM) surface, which guarantees topological correctness. This mesh is further deformed to estimate the GM surface. We compare our method to recon-all-clinical (RAC), an implicit surface reconstruction method which is currently the only other tool capable of processing heterogeneous clinical MR scans, on ADNI and a large clinical dataset (n = 1,332). We show a ∼50\% reduction in cortical thickness error (from 0.50 to 0.24 mm) with respect to RAC and better recovery of the aging-related cortical thinning patterns detected by FreeSurfer on high-resolution T1w scans. Our method enables fast and accurate surface reconstruction of clinical scans, allowing studies (1) with sample sizes far beyond what is feasible in a research setting, and (2) of clinical populations that are difficult to enroll in research studies. The code is publicly available at https://github.com/simnibs/brainnet.",

keywords = "Clinical data, Cortical surface modeling, Deep learning",

author = "Nielsen, \{Jesper Duemose\} and Karthik Gopinath and Andrew Hoopes and Adrian Dalca and Colin Magdamo and Steven Arnold and Sudeshna Das and Axel Thielscher and Iglesias, \{Juan Eugenio\} and Oula Puonti",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive license to Springer Nature Switzerland AG 2026.; 16th International Workshop on Machine Learning in Medical Imaging, MLMI 2025 was held in conjunction with the 28th International Conference on Medical Image Computing and Computer Assisted Intervention, MICCAI 2025 ; Conference date: 23-09-2025 Through 23-09-2025",

year = "2026",

doi = "10.1007/978-3-032-09513-8\_21",

language = "English",

isbn = "9783032095121",

series = "Lecture Notes in Computer Science",

publisher = "Springer",

pages = "212--223",

editor = "Zhiming Cui and Islem Rekik and Heung-IL Suk and Xi Ouyang and Kaicong Sun and Sheng Wang",

booktitle = "Machine Learning in Medical Imaging - 16th International Workshop, MLMI 2025, Held in Conjunction with MICCAI 2025, Proceedings",

}

TY - GEN

T1 - End-to-End Cortical Surface Reconstruction from Clinical Magnetic Resonance Images

AU - Nielsen, Jesper Duemose

AU - Gopinath, Karthik

AU - Hoopes, Andrew

AU - Dalca, Adrian

AU - Magdamo, Colin

AU - Arnold, Steven

AU - Das, Sudeshna

AU - Thielscher, Axel

AU - Iglesias, Juan Eugenio

AU - Puonti, Oula

N1 - Publisher Copyright: © The Author(s), under exclusive license to Springer Nature Switzerland AG 2026.

PY - 2026

Y1 - 2026

N2 - Surface-based cortical analysis is valuable for a variety of neuroimaging tasks, such as spatial normalization, parcellation, and gray matter (GM) thickness estimation. However, most tools for estimating cortical surfaces work exclusively on scans with at least 1 mm isotropic resolution and are tuned to a specific magnetic resonance (MR) contrast, often T1-weighted (T1w). This precludes application using most clinical MR scans, which are very heterogeneous in terms of contrast and resolution. Here, we use synthetic domain-randomized data to train the first neural network for explicit estimation of cortical surfaces from scans of any contrast and resolution, without retraining. Our method deforms a template mesh to the white matter (WM) surface, which guarantees topological correctness. This mesh is further deformed to estimate the GM surface. We compare our method to recon-all-clinical (RAC), an implicit surface reconstruction method which is currently the only other tool capable of processing heterogeneous clinical MR scans, on ADNI and a large clinical dataset (n = 1,332). We show a ∼50% reduction in cortical thickness error (from 0.50 to 0.24 mm) with respect to RAC and better recovery of the aging-related cortical thinning patterns detected by FreeSurfer on high-resolution T1w scans. Our method enables fast and accurate surface reconstruction of clinical scans, allowing studies (1) with sample sizes far beyond what is feasible in a research setting, and (2) of clinical populations that are difficult to enroll in research studies. The code is publicly available at https://github.com/simnibs/brainnet.

AB - Surface-based cortical analysis is valuable for a variety of neuroimaging tasks, such as spatial normalization, parcellation, and gray matter (GM) thickness estimation. However, most tools for estimating cortical surfaces work exclusively on scans with at least 1 mm isotropic resolution and are tuned to a specific magnetic resonance (MR) contrast, often T1-weighted (T1w). This precludes application using most clinical MR scans, which are very heterogeneous in terms of contrast and resolution. Here, we use synthetic domain-randomized data to train the first neural network for explicit estimation of cortical surfaces from scans of any contrast and resolution, without retraining. Our method deforms a template mesh to the white matter (WM) surface, which guarantees topological correctness. This mesh is further deformed to estimate the GM surface. We compare our method to recon-all-clinical (RAC), an implicit surface reconstruction method which is currently the only other tool capable of processing heterogeneous clinical MR scans, on ADNI and a large clinical dataset (n = 1,332). We show a ∼50% reduction in cortical thickness error (from 0.50 to 0.24 mm) with respect to RAC and better recovery of the aging-related cortical thinning patterns detected by FreeSurfer on high-resolution T1w scans. Our method enables fast and accurate surface reconstruction of clinical scans, allowing studies (1) with sample sizes far beyond what is feasible in a research setting, and (2) of clinical populations that are difficult to enroll in research studies. The code is publicly available at https://github.com/simnibs/brainnet.

KW - Clinical data

KW - Cortical surface modeling

KW - Deep learning

UR - https://www.scopus.com/pages/publications/105027584460

U2 - 10.1007/978-3-032-09513-8_21

DO - 10.1007/978-3-032-09513-8_21

M3 - Article in proceedings

AN - SCOPUS:105027584460

SN - 9783032095121

T3 - Lecture Notes in Computer Science

SP - 212

EP - 223

BT - Machine Learning in Medical Imaging - 16th International Workshop, MLMI 2025, Held in Conjunction with MICCAI 2025, Proceedings

A2 - Cui, Zhiming

A2 - Rekik, Islem

A2 - Suk, Heung-IL

A2 - Ouyang, Xi

A2 - Sun, Kaicong

A2 - Wang, Sheng

PB - Springer

T2 - 16th International Workshop on Machine Learning in Medical Imaging, MLMI 2025 was held in conjunction with the 28th International Conference on Medical Image Computing and Computer Assisted Intervention, MICCAI 2025

Y2 - 23 September 2025 through 23 September 2025