Glioblastoma Surgery Imaging-Reporting and Data System: Validation and Performance of the Automated Segmentation Task

David Bouget; Roelant S Eijgelaar; André Pedersen; Ivar Kommers; Hilko Ardon; Frederik Barkhof; Lorenzo Bello; Mitchel S Berger; Marco Conti Nibali; Julia Furtner; Even Hovig Fyllingen; Shawn Hervey-Jumper; Albert J S Idema; Barbara Kiesel; Alfred Kloet; Emmanuel Mandonnet; Domenique M J Müller; Pierre A Robe; Marco Rossi; Lisa M Sagberg; Tommaso Sciortino; Wimar A Van den Brink; Michiel Wagemakers; Georg Widhalm; Marnix G Witte; Aeilko H Zwinderman; Ingerid Reinertsen; Philip C De Witt Hamer; Ole Solheim

doi:https://doi.org/10.3390/cancers13184674

Glioblastoma Surgery Imaging-Reporting and Data System: Validation and Performance of the Automated Segmentation Task

David Bouget, Roelant S Eijgelaar, André Pedersen, Ivar Kommers, Hilko Ardon, Frederik Barkhof, Lorenzo Bello, Mitchel S Berger, Marco Conti Nibali, Julia Furtner, Even Hovig Fyllingen, Shawn Hervey-Jumper, Albert J S Idema, Barbara Kiesel, Alfred Kloet, Emmanuel Mandonnet, Domenique M J Müller, Pierre A Robe, Marco Rossi, Lisa M SagbergTommaso Sciortino, Wimar A Van den Brink, Michiel Wagemakers, Georg Widhalm, Marnix G Witte, Aeilko H Zwinderman, Ingerid Reinertsen, Philip C De Witt Hamer, Ole Solheim

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

8 Citations (Scopus)

Abstract

For patients with presumed glioblastoma, essential tumor characteristics are determined from preoperative MR images to optimize the treatment strategy. This procedure is time-consuming and subjective, if performed by crude eyeballing or manually. The standardized GSI-RADS aims to provide neurosurgeons with automatic tumor segmentations to extract tumor features rapidly and objectively. In this study, we improved automatic tumor segmentation and compared the agreement with manual raters, describe the technical details of the different components of GSI-RADS, and determined their speed. Two recent neural network architectures were considered for the segmentation task: nnU-Net and AGU-Net. Two preprocessing schemes were introduced to investigate the tradeoff between performance and processing speed. A summarized description of the tumor feature extraction and standardized reporting process is included. The trained architectures for automatic segmentation and the code for computing the standardized report are distributed as open-source and as open-access software. Validation studies were performed on a dataset of 1594 gadolinium-enhanced T1-weighted MRI volumes from 13 hospitals and 293 T1-weighted MRI volumes from the BraTS challenge. The glioblastoma tumor core segmentation reached a Dice score slightly below 90%, a patientwise F1-score close to 99%, and a 95th percentile Hausdorff distance slightly below 4.0 mm on average with either architecture and the heavy preprocessing scheme. A patient MRI volume can be segmented in less than one minute, and a standardized report can be generated in up to five minutes. The proposed GSI-RADS software showed robust performance on a large collection of MRI volumes from various hospitals and generated results within a reasonable runtime.

Original language	English
Article number	4674
Journal	Cancers
Volume	13
Issue number	18
DOIs	https://doi.org/10.3390/cancers13184674
Publication status	Published - 17 Sept 2021

Keywords

3D segmentation
Computer-assisted image processing
Deep learning
Glioblastoma
Magnetic resonance imaging
Neuroimaging

Access to Document

https://doi.org/10.3390/cancers13184674

Cite this

Bouget, D., Eijgelaar, R. S., Pedersen, A., Kommers, I., Ardon, H., Barkhof, F., Bello, L., Berger, M. S., Nibali, M. C., Furtner, J., Fyllingen, E. H., Hervey-Jumper, S., Idema, A. J. S., Kiesel, B., Kloet, A., Mandonnet, E., Müller, D. M. J., Robe, P. A., Rossi, M., ... Solheim, O. (2021). Glioblastoma Surgery Imaging-Reporting and Data System: Validation and Performance of the Automated Segmentation Task. Cancers, 13(18), Article 4674. https://doi.org/10.3390/cancers13184674

@article{90561bc1540c4ac4b446500072272dde,

title = "Glioblastoma Surgery Imaging-Reporting and Data System: Validation and Performance of the Automated Segmentation Task",

abstract = "For patients with presumed glioblastoma, essential tumor characteristics are determined from preoperative MR images to optimize the treatment strategy. This procedure is time-consuming and subjective, if performed by crude eyeballing or manually. The standardized GSI-RADS aims to provide neurosurgeons with automatic tumor segmentations to extract tumor features rapidly and objectively. In this study, we improved automatic tumor segmentation and compared the agreement with manual raters, describe the technical details of the different components of GSI-RADS, and determined their speed. Two recent neural network architectures were considered for the segmentation task: nnU-Net and AGU-Net. Two preprocessing schemes were introduced to investigate the tradeoff between performance and processing speed. A summarized description of the tumor feature extraction and standardized reporting process is included. The trained architectures for automatic segmentation and the code for computing the standardized report are distributed as open-source and as open-access software. Validation studies were performed on a dataset of 1594 gadolinium-enhanced T1-weighted MRI volumes from 13 hospitals and 293 T1-weighted MRI volumes from the BraTS challenge. The glioblastoma tumor core segmentation reached a Dice score slightly below 90%, a patientwise F1-score close to 99%, and a 95th percentile Hausdorff distance slightly below 4.0 mm on average with either architecture and the heavy preprocessing scheme. A patient MRI volume can be segmented in less than one minute, and a standardized report can be generated in up to five minutes. The proposed GSI-RADS software showed robust performance on a large collection of MRI volumes from various hospitals and generated results within a reasonable runtime.",

keywords = "3D segmentation, Computer-assisted image processing, Deep learning, Glioblastoma, Magnetic resonance imaging, Neuroimaging",

author = "David Bouget and Eijgelaar, {Roelant S} and Andr{\'e} Pedersen and Ivar Kommers and Hilko Ardon and Frederik Barkhof and Lorenzo Bello and Berger, {Mitchel S} and Nibali, {Marco Conti} and Julia Furtner and Fyllingen, {Even Hovig} and Shawn Hervey-Jumper and Idema, {Albert J S} and Barbara Kiesel and Alfred Kloet and Emmanuel Mandonnet and M{\"u}ller, {Domenique M J} and Robe, {Pierre A} and Marco Rossi and Sagberg, {Lisa M} and Tommaso Sciortino and {Van den Brink}, {Wimar A} and Michiel Wagemakers and Georg Widhalm and Witte, {Marnix G} and Zwinderman, {Aeilko H} and Ingerid Reinertsen and {De Witt Hamer}, {Philip C} and Ole Solheim",

note = "Funding Information: Funding: This research was supported by an unrestricted grant of Stichting Hanarth fonds, “Machine learning for better neurosurgical decisions in patients with glioblastoma”; a grant for public–private partnerships (Amsterdam UMC PPP-grant) sponsored by the Dutch government (Ministry of Economic Affairs) through the Rijksdienst voor Ondernemend Nederland (RVO) and Topsector Life Sciences & Health (LSH), “Picturing predictions for patients with brain tumors”; a grant from the Inno-vative Medical Devices Initiative program, Project Number 10-10400-96-14003; financed by the Netherlands Organisation for Scientific Research (NWO), 2020.027; a grant from the Dutch Cancer Society, VU2014-7113; the Anita Veldman foundation, CCA2018-2-17; the Norwegian National Advisory Unit for Ultrasound and Image-guided Therapy. F.B. is supported by the NIHR biomedical research center at UCLH. Funding Information: Acknowledgments: This work was conducted both at (i) the digital labs at HUNT Cloud, the Norwegian University of Science and Technology, Trondheim, Norway, and (ii) the Dutch national e-infrastructure with the support of SURF Cooperative and the Translational Research IT (TraIT) project, an initiative from the Center for Translational Molecular Medicine (CTMM). Publisher Copyright: {\textcopyright} 2021 by the authors. Licensee MDPI, Basel, Switzerland.",

year = "2021",

month = sep,

day = "17",

doi = "https://doi.org/10.3390/cancers13184674",

language = "English",

volume = "13",

journal = "Cancers",

issn = "2072-6694",

publisher = "MDPI Multidisciplinary Digital Publishing Institute",

number = "18",

}

Bouget, D, Eijgelaar, RS, Pedersen, A, Kommers, I, Ardon, H, Barkhof, F, Bello, L, Berger, MS, Nibali, MC, Furtner, J, Fyllingen, EH, Hervey-Jumper, S, Idema, AJS, Kiesel, B, Kloet, A, Mandonnet, E, Müller, DMJ, Robe, PA, Rossi, M, Sagberg, LM, Sciortino, T, Van den Brink, WA, Wagemakers, M, Widhalm, G, Witte, MG, Zwinderman, AH, Reinertsen, I, De Witt Hamer, PC & Solheim, O 2021, 'Glioblastoma Surgery Imaging-Reporting and Data System: Validation and Performance of the Automated Segmentation Task', Cancers, vol. 13, no. 18, 4674. https://doi.org/10.3390/cancers13184674

TY - JOUR

T1 - Glioblastoma Surgery Imaging-Reporting and Data System

T2 - Validation and Performance of the Automated Segmentation Task

AU - Bouget, David

AU - Eijgelaar, Roelant S

AU - Pedersen, André

AU - Kommers, Ivar

AU - Ardon, Hilko

AU - Barkhof, Frederik

AU - Bello, Lorenzo

AU - Berger, Mitchel S

AU - Nibali, Marco Conti

AU - Furtner, Julia

AU - Fyllingen, Even Hovig

AU - Hervey-Jumper, Shawn

AU - Idema, Albert J S

AU - Kiesel, Barbara

AU - Kloet, Alfred

AU - Mandonnet, Emmanuel

AU - Müller, Domenique M J

AU - Robe, Pierre A

AU - Rossi, Marco

AU - Sagberg, Lisa M

AU - Sciortino, Tommaso

AU - Van den Brink, Wimar A

AU - Wagemakers, Michiel

AU - Widhalm, Georg

AU - Witte, Marnix G

AU - Zwinderman, Aeilko H

AU - Reinertsen, Ingerid

AU - De Witt Hamer, Philip C

AU - Solheim, Ole

N1 - Funding Information: Funding: This research was supported by an unrestricted grant of Stichting Hanarth fonds, “Machine learning for better neurosurgical decisions in patients with glioblastoma”; a grant for public–private partnerships (Amsterdam UMC PPP-grant) sponsored by the Dutch government (Ministry of Economic Affairs) through the Rijksdienst voor Ondernemend Nederland (RVO) and Topsector Life Sciences & Health (LSH), “Picturing predictions for patients with brain tumors”; a grant from the Inno-vative Medical Devices Initiative program, Project Number 10-10400-96-14003; financed by the Netherlands Organisation for Scientific Research (NWO), 2020.027; a grant from the Dutch Cancer Society, VU2014-7113; the Anita Veldman foundation, CCA2018-2-17; the Norwegian National Advisory Unit for Ultrasound and Image-guided Therapy. F.B. is supported by the NIHR biomedical research center at UCLH. Funding Information: Acknowledgments: This work was conducted both at (i) the digital labs at HUNT Cloud, the Norwegian University of Science and Technology, Trondheim, Norway, and (ii) the Dutch national e-infrastructure with the support of SURF Cooperative and the Translational Research IT (TraIT) project, an initiative from the Center for Translational Molecular Medicine (CTMM). Publisher Copyright: © 2021 by the authors. Licensee MDPI, Basel, Switzerland.

PY - 2021/9/17

Y1 - 2021/9/17

N2 - For patients with presumed glioblastoma, essential tumor characteristics are determined from preoperative MR images to optimize the treatment strategy. This procedure is time-consuming and subjective, if performed by crude eyeballing or manually. The standardized GSI-RADS aims to provide neurosurgeons with automatic tumor segmentations to extract tumor features rapidly and objectively. In this study, we improved automatic tumor segmentation and compared the agreement with manual raters, describe the technical details of the different components of GSI-RADS, and determined their speed. Two recent neural network architectures were considered for the segmentation task: nnU-Net and AGU-Net. Two preprocessing schemes were introduced to investigate the tradeoff between performance and processing speed. A summarized description of the tumor feature extraction and standardized reporting process is included. The trained architectures for automatic segmentation and the code for computing the standardized report are distributed as open-source and as open-access software. Validation studies were performed on a dataset of 1594 gadolinium-enhanced T1-weighted MRI volumes from 13 hospitals and 293 T1-weighted MRI volumes from the BraTS challenge. The glioblastoma tumor core segmentation reached a Dice score slightly below 90%, a patientwise F1-score close to 99%, and a 95th percentile Hausdorff distance slightly below 4.0 mm on average with either architecture and the heavy preprocessing scheme. A patient MRI volume can be segmented in less than one minute, and a standardized report can be generated in up to five minutes. The proposed GSI-RADS software showed robust performance on a large collection of MRI volumes from various hospitals and generated results within a reasonable runtime.

AB - For patients with presumed glioblastoma, essential tumor characteristics are determined from preoperative MR images to optimize the treatment strategy. This procedure is time-consuming and subjective, if performed by crude eyeballing or manually. The standardized GSI-RADS aims to provide neurosurgeons with automatic tumor segmentations to extract tumor features rapidly and objectively. In this study, we improved automatic tumor segmentation and compared the agreement with manual raters, describe the technical details of the different components of GSI-RADS, and determined their speed. Two recent neural network architectures were considered for the segmentation task: nnU-Net and AGU-Net. Two preprocessing schemes were introduced to investigate the tradeoff between performance and processing speed. A summarized description of the tumor feature extraction and standardized reporting process is included. The trained architectures for automatic segmentation and the code for computing the standardized report are distributed as open-source and as open-access software. Validation studies were performed on a dataset of 1594 gadolinium-enhanced T1-weighted MRI volumes from 13 hospitals and 293 T1-weighted MRI volumes from the BraTS challenge. The glioblastoma tumor core segmentation reached a Dice score slightly below 90%, a patientwise F1-score close to 99%, and a 95th percentile Hausdorff distance slightly below 4.0 mm on average with either architecture and the heavy preprocessing scheme. A patient MRI volume can be segmented in less than one minute, and a standardized report can be generated in up to five minutes. The proposed GSI-RADS software showed robust performance on a large collection of MRI volumes from various hospitals and generated results within a reasonable runtime.

KW - 3D segmentation

KW - Computer-assisted image processing

KW - Deep learning

KW - Glioblastoma

KW - Magnetic resonance imaging

KW - Neuroimaging

UR - http://www.scopus.com/inward/record.url?scp=85115054009&partnerID=8YFLogxK

U2 - https://doi.org/10.3390/cancers13184674

DO - https://doi.org/10.3390/cancers13184674

M3 - Article

C2 - 34572900

SN - 2072-6694

VL - 13

JO - Cancers

JF - Cancers

IS - 18

M1 - 4674

ER -

Glioblastoma Surgery Imaging-Reporting and Data System: Validation and Performance of the Automated Segmentation Task

Abstract

Keywords

Access to Document

Other files and links

Cite this