Automatic and standardized reporting of perioperative MRIs in patients with central nervous system tumors

David Bouget; Mathilde Gajda Faanes; Asgeir Store Jakola; Frederik Barkhof; Hilko Ardon; Lorenzo Bello; Mitchel S. Berger; Shawn L. Hervey-Jumper; Julia Furtner; Albert J.S. Idema; Barbara Kiesel; Georg Widhalm; Rishi Nandoe Tewarie; Emmanuel Mandonnet; Pierre A. Robe; Michiel Wagemakers; Timothy R. Smith; Philip C. De Witt Hamer; Ole Solheim; Ingerid Reinertsen

doi:10.3389/fneur.2025.1707481

Automatic and standardized reporting of perioperative MRIs in patients with central nervous system tumors

David Bouget^*
, Mathilde Gajda Faanes
, Asgeir Store Jakola
, Frederik Barkhof
, Hilko Ardon
, Lorenzo Bello
, Mitchel S. Berger
, Shawn L. Hervey-Jumper
, Julia Furtner
, Albert J.S. Idema
, Barbara Kiesel
, Georg Widhalm
, Rishi Nandoe Tewarie
, Emmanuel Mandonnet
, Pierre A. Robe
, Michiel Wagemakers
, Timothy R. Smith
, Philip C. De Witt Hamer
, Ole Solheim
, Ingerid Reinertsen

^*Corresponding author for this work

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

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Abstract

Introduction: Magnetic resonance (MR) imaging is essential for diagnosing central nervous system (CNS) tumors, guiding surgical planning, treatment decisions, and assessing postoperative outcomes and complications. While recent work has advanced automated tumor segmentation and report generation, most efforts have focused on preoperative data, with limited attention to postoperative imaging analysis. Methods: This study introduces a comprehensive pipeline for standardized postsurgical reporting in CNS tumors. Using the Attention U-Net architecture, segmentation models were trained, independently targeting the preoperative tumor core, non-enhancing tumor core, postoperative contrast-enhancing residual tumor, and resection cavity. In the process, the influence of varying MR sequence combinations was assessed. Additionally, MR sequence classification and tumor type identification for contrast-enhancing lesions were explored using the DenseNet architecture. The models were integrated seamlessly into an automated and standardized reporting pipeline, following the RANO 2.0 guidelines. Training was conducted on multicentric datasets comprising 2000 to 7000 patients, incorporating both private and public data, using a 5-fold cross-validation. Results: Evaluation included patient-, voxel-, and object-wise metrics, with benchmarking against the latest BraTS challenge results. The segmentation models achieved average voxel-wise Dice scores of 87%, 66%, 70%, and 77% for the tumor core, non-enhancing tumor core, contrast-enhancing residual tumor, and resection cavity, respectively. Classification models reached 99.5% balanced accuracy in MR sequence classification and 80% in tumor type classification. Discussion: The pipeline presented in this study enables robust, automated segmentation, MR sequence classification, and standardized report generation aligned with RANO 2.0 guidelines, enhancing postoperative evaluation and clinical decision-making. The proposed models and methods were integrated into Raidionics, open-source software platform for CNS tumor analysis, now including a dedicated module for postsurgical analysis.

Original language	English
Article number	1707481
Journal	Frontiers in Neurology
Volume	16
DOIs	https://doi.org/10.3389/fneur.2025.1707481
Publication status	Published - 2026

Keywords

3D segmentation
attention U-net
CNS tumor
RADS
reporting

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Bouget, D., Faanes, M. G., Jakola, A. S., Barkhof, F., Ardon, H., Bello, L., Berger, M. S., Hervey-Jumper, S. L., Furtner, J., Idema, A. J. S., Kiesel, B., Widhalm, G., Tewarie, R. N., Mandonnet, E., Robe, P. A., Wagemakers, M., Smith, T. R., De Witt Hamer, P. C., Solheim, O., & Reinertsen, I. (2026). Automatic and standardized reporting of perioperative MRIs in patients with central nervous system tumors. Frontiers in Neurology, 16, Article 1707481. https://doi.org/10.3389/fneur.2025.1707481

@article{fef87f3d803d47efb57b90bca06dd3f9,

title = "Automatic and standardized reporting of perioperative MRIs in patients with central nervous system tumors",

abstract = "Introduction: Magnetic resonance (MR) imaging is essential for diagnosing central nervous system (CNS) tumors, guiding surgical planning, treatment decisions, and assessing postoperative outcomes and complications. While recent work has advanced automated tumor segmentation and report generation, most efforts have focused on preoperative data, with limited attention to postoperative imaging analysis. Methods: This study introduces a comprehensive pipeline for standardized postsurgical reporting in CNS tumors. Using the Attention U-Net architecture, segmentation models were trained, independently targeting the preoperative tumor core, non-enhancing tumor core, postoperative contrast-enhancing residual tumor, and resection cavity. In the process, the influence of varying MR sequence combinations was assessed. Additionally, MR sequence classification and tumor type identification for contrast-enhancing lesions were explored using the DenseNet architecture. The models were integrated seamlessly into an automated and standardized reporting pipeline, following the RANO 2.0 guidelines. Training was conducted on multicentric datasets comprising 2000 to 7000 patients, incorporating both private and public data, using a 5-fold cross-validation. Results: Evaluation included patient-, voxel-, and object-wise metrics, with benchmarking against the latest BraTS challenge results. The segmentation models achieved average voxel-wise Dice scores of 87\%, 66\%, 70\%, and 77\% for the tumor core, non-enhancing tumor core, contrast-enhancing residual tumor, and resection cavity, respectively. Classification models reached 99.5\% balanced accuracy in MR sequence classification and 80\% in tumor type classification. Discussion: The pipeline presented in this study enables robust, automated segmentation, MR sequence classification, and standardized report generation aligned with RANO 2.0 guidelines, enhancing postoperative evaluation and clinical decision-making. The proposed models and methods were integrated into Raidionics, open-source software platform for CNS tumor analysis, now including a dedicated module for postsurgical analysis.",

keywords = "3D segmentation, attention U-net, CNS tumor, RADS, reporting",

author = "David Bouget and Faanes, \{Mathilde Gajda\} and Jakola, \{Asgeir Store\} and Frederik Barkhof and Hilko Ardon and Lorenzo Bello and Berger, \{Mitchel S.\} and Hervey-Jumper, \{Shawn L.\} and Julia Furtner and Idema, \{Albert J.S.\} and Barbara Kiesel and Georg Widhalm and Tewarie, \{Rishi Nandoe\} and Emmanuel Mandonnet and Robe, \{Pierre A.\} and Michiel Wagemakers and Smith, \{Timothy R.\} and \{De Witt Hamer\}, \{Philip C.\} and Ole Solheim and Ingerid Reinertsen",

note = "Publisher Copyright: Copyright {\textcopyright} 2026 Bouget, Faanes, Jakola, Barkhof, Ardon, Bello, Berger, Hervey-Jumper, Furtner, Idema, Kiesel, Widhalm, Tewarie, Mandonnet, Robe, Wagemakers, Smith, De Witt Hamer, Solheim and Reinertsen.",

year = "2026",

doi = "10.3389/fneur.2025.1707481",

language = "English",

volume = "16",

journal = "Frontiers in Neurology",

issn = "1664-2295",

publisher = "Frontiers Media S. A.",

}

Bouget, D, Faanes, MG, Jakola, AS, Barkhof, F, Ardon, H, Bello, L, Berger, MS, Hervey-Jumper, SL, Furtner, J, Idema, AJS, Kiesel, B, Widhalm, G, Tewarie, RN, Mandonnet, E, Robe, PA, Wagemakers, M, Smith, TR, De Witt Hamer, PC, Solheim, O & Reinertsen, I 2026, 'Automatic and standardized reporting of perioperative MRIs in patients with central nervous system tumors', Frontiers in Neurology, vol. 16, 1707481. https://doi.org/10.3389/fneur.2025.1707481

TY - JOUR

T1 - Automatic and standardized reporting of perioperative MRIs in patients with central nervous system tumors

AU - Bouget, David

AU - Faanes, Mathilde Gajda

AU - Jakola, Asgeir Store

AU - Barkhof, Frederik

AU - Ardon, Hilko

AU - Bello, Lorenzo

AU - Berger, Mitchel S.

AU - Hervey-Jumper, Shawn L.

AU - Furtner, Julia

AU - Idema, Albert J.S.

AU - Kiesel, Barbara

AU - Widhalm, Georg

AU - Tewarie, Rishi Nandoe

AU - Mandonnet, Emmanuel

AU - Robe, Pierre A.

AU - Wagemakers, Michiel

AU - Smith, Timothy R.

AU - De Witt Hamer, Philip C.

AU - Solheim, Ole

AU - Reinertsen, Ingerid

N1 - Publisher Copyright: Copyright © 2026 Bouget, Faanes, Jakola, Barkhof, Ardon, Bello, Berger, Hervey-Jumper, Furtner, Idema, Kiesel, Widhalm, Tewarie, Mandonnet, Robe, Wagemakers, Smith, De Witt Hamer, Solheim and Reinertsen.

PY - 2026

Y1 - 2026

N2 - Introduction: Magnetic resonance (MR) imaging is essential for diagnosing central nervous system (CNS) tumors, guiding surgical planning, treatment decisions, and assessing postoperative outcomes and complications. While recent work has advanced automated tumor segmentation and report generation, most efforts have focused on preoperative data, with limited attention to postoperative imaging analysis. Methods: This study introduces a comprehensive pipeline for standardized postsurgical reporting in CNS tumors. Using the Attention U-Net architecture, segmentation models were trained, independently targeting the preoperative tumor core, non-enhancing tumor core, postoperative contrast-enhancing residual tumor, and resection cavity. In the process, the influence of varying MR sequence combinations was assessed. Additionally, MR sequence classification and tumor type identification for contrast-enhancing lesions were explored using the DenseNet architecture. The models were integrated seamlessly into an automated and standardized reporting pipeline, following the RANO 2.0 guidelines. Training was conducted on multicentric datasets comprising 2000 to 7000 patients, incorporating both private and public data, using a 5-fold cross-validation. Results: Evaluation included patient-, voxel-, and object-wise metrics, with benchmarking against the latest BraTS challenge results. The segmentation models achieved average voxel-wise Dice scores of 87%, 66%, 70%, and 77% for the tumor core, non-enhancing tumor core, contrast-enhancing residual tumor, and resection cavity, respectively. Classification models reached 99.5% balanced accuracy in MR sequence classification and 80% in tumor type classification. Discussion: The pipeline presented in this study enables robust, automated segmentation, MR sequence classification, and standardized report generation aligned with RANO 2.0 guidelines, enhancing postoperative evaluation and clinical decision-making. The proposed models and methods were integrated into Raidionics, open-source software platform for CNS tumor analysis, now including a dedicated module for postsurgical analysis.

AB - Introduction: Magnetic resonance (MR) imaging is essential for diagnosing central nervous system (CNS) tumors, guiding surgical planning, treatment decisions, and assessing postoperative outcomes and complications. While recent work has advanced automated tumor segmentation and report generation, most efforts have focused on preoperative data, with limited attention to postoperative imaging analysis. Methods: This study introduces a comprehensive pipeline for standardized postsurgical reporting in CNS tumors. Using the Attention U-Net architecture, segmentation models were trained, independently targeting the preoperative tumor core, non-enhancing tumor core, postoperative contrast-enhancing residual tumor, and resection cavity. In the process, the influence of varying MR sequence combinations was assessed. Additionally, MR sequence classification and tumor type identification for contrast-enhancing lesions were explored using the DenseNet architecture. The models were integrated seamlessly into an automated and standardized reporting pipeline, following the RANO 2.0 guidelines. Training was conducted on multicentric datasets comprising 2000 to 7000 patients, incorporating both private and public data, using a 5-fold cross-validation. Results: Evaluation included patient-, voxel-, and object-wise metrics, with benchmarking against the latest BraTS challenge results. The segmentation models achieved average voxel-wise Dice scores of 87%, 66%, 70%, and 77% for the tumor core, non-enhancing tumor core, contrast-enhancing residual tumor, and resection cavity, respectively. Classification models reached 99.5% balanced accuracy in MR sequence classification and 80% in tumor type classification. Discussion: The pipeline presented in this study enables robust, automated segmentation, MR sequence classification, and standardized report generation aligned with RANO 2.0 guidelines, enhancing postoperative evaluation and clinical decision-making. The proposed models and methods were integrated into Raidionics, open-source software platform for CNS tumor analysis, now including a dedicated module for postsurgical analysis.

KW - 3D segmentation

KW - attention U-net

KW - CNS tumor

KW - RADS

KW - reporting

UR - https://www.scopus.com/pages/publications/105030568525

U2 - 10.3389/fneur.2025.1707481

DO - 10.3389/fneur.2025.1707481

M3 - Article

AN - SCOPUS:105030568525

SN - 1664-2295

VL - 16

JO - Frontiers in Neurology

JF - Frontiers in Neurology

M1 - 1707481

ER -

Automatic and standardized reporting of perioperative MRIs in patients with central nervous system tumors

Abstract

Keywords

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