A semi-automatic segmentation method for meningioma developed using a variational approach model

Liam Burrows; Jay Patel; Abdurrahman I Islim; Michael D Jenkinson; Samantha J Mills; Ke Chen

doi:10.1177/19714009231224442

A semi-automatic segmentation method for meningioma developed using a variational approach model

Liam Burrows
, Jay Patel
, Abdurrahman I Islim
, Michael D Jenkinson
, Samantha J Mills
, Ke Chen

Division of Neuroscience

University of Liverpool
The Walton Centre NHS Foundation Trust

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

Abstract

BACKGROUND: Meningioma is the commonest primary brain tumour. Volumetric post-contrast magnetic resonance imaging (MRI) is recognised as gold standard for delineation of meningioma volume but is hindered by manual processing times. We aimed to investigate the utility of a model-based variational approach in segmenting meningioma.

METHODS: A database of patients with a meningioma (2007-2015) was queried for patients with a contrast-enhanced volumetric MRI, who had consented to a research tissue biobank. Manual segmentation by a neuroradiologist was performed and results were compared to the mathematical model, using a battery of tests including the Sørensen-Dice coefficient (DICE) and JACCARD index. A publicly available meningioma dataset (708 segmented T1 contrast-enhanced slices) was also used to test the reliability of the model.

RESULTS: 49 meningioma cases were included. The most common meningioma location was convexity ( n = 15, 30.6%). The mathematical model segmented all but one incidental meningioma, which failed due to the lack of contrast uptake. The median meningioma volume by manual segmentation was 19.0 cm 3 (IQR 4.9-31.2). The median meningioma volume using the mathematical model was 16.9 cm 3 (IQR 4.6-28.34). The mean DICE score was 0.90 (SD = 0.04). The mean JACCARD index was 0.82 (SD = 0.07). For the publicly available dataset, the mean DICE and JACCARD scores were 0.90 (SD = 0.06) and 0.82 (SD = 0.10), respectively.

CONCLUSIONS: Segmentation of meningioma volume using the proposed mathematical model was possible with accurate results. Application of this model on contrast-enhanced volumetric imaging may help reduce work burden on neuroradiologists with the increasing number in meningioma diagnoses.

Original language	English
Pages (from-to)	199-205
Number of pages	7
Journal	The neuroradiology journal
Volume	37
Issue number	2
Early online date	26 Dec 2023
DOIs	https://doi.org/10.1177/19714009231224442
Publication status	Published - 1 Apr 2024

Keywords

Humans
Meningioma/diagnostic imaging
Reproducibility of Results
Image Processing, Computer-Assisted/methods
Magnetic Resonance Imaging/methods
Meningeal Neoplasms/diagnostic imaging

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10.1177/19714009231224442Licence: CC BY-NC

Cite this

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title = "A semi-automatic segmentation method for meningioma developed using a variational approach model",

abstract = "BACKGROUND: Meningioma is the commonest primary brain tumour. Volumetric post-contrast magnetic resonance imaging (MRI) is recognised as gold standard for delineation of meningioma volume but is hindered by manual processing times. We aimed to investigate the utility of a model-based variational approach in segmenting meningioma.METHODS: A database of patients with a meningioma (2007-2015) was queried for patients with a contrast-enhanced volumetric MRI, who had consented to a research tissue biobank. Manual segmentation by a neuroradiologist was performed and results were compared to the mathematical model, using a battery of tests including the S{\o}rensen-Dice coefficient (DICE) and JACCARD index. A publicly available meningioma dataset (708 segmented T1 contrast-enhanced slices) was also used to test the reliability of the model.RESULTS: 49 meningioma cases were included. The most common meningioma location was convexity ( n = 15, 30.6\%). The mathematical model segmented all but one incidental meningioma, which failed due to the lack of contrast uptake. The median meningioma volume by manual segmentation was 19.0 cm 3 (IQR 4.9-31.2). The median meningioma volume using the mathematical model was 16.9 cm 3 (IQR 4.6-28.34). The mean DICE score was 0.90 (SD = 0.04). The mean JACCARD index was 0.82 (SD = 0.07). For the publicly available dataset, the mean DICE and JACCARD scores were 0.90 (SD = 0.06) and 0.82 (SD = 0.10), respectively. CONCLUSIONS: Segmentation of meningioma volume using the proposed mathematical model was possible with accurate results. Application of this model on contrast-enhanced volumetric imaging may help reduce work burden on neuroradiologists with the increasing number in meningioma diagnoses.",

keywords = "Humans, Meningioma/diagnostic imaging, Reproducibility of Results, Image Processing, Computer-Assisted/methods, Magnetic Resonance Imaging/methods, Meningeal Neoplasms/diagnostic imaging",

author = "Liam Burrows and Jay Patel and Islim, \{Abdurrahman I\} and Jenkinson, \{Michael D\} and Mills, \{Samantha J\} and Ke Chen",

year = "2024",

month = apr,

day = "1",

doi = "10.1177/19714009231224442",

language = "English",

volume = "37",

pages = "199--205",

journal = "The neuroradiology journal",

issn = "1971-4009",

publisher = "SAGE Publications Inc.",

number = "2",

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T1 - A semi-automatic segmentation method for meningioma developed using a variational approach model

AU - Burrows, Liam

AU - Patel, Jay

AU - Islim, Abdurrahman I

AU - Jenkinson, Michael D

AU - Mills, Samantha J

AU - Chen, Ke

PY - 2024/4/1

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N2 - BACKGROUND: Meningioma is the commonest primary brain tumour. Volumetric post-contrast magnetic resonance imaging (MRI) is recognised as gold standard for delineation of meningioma volume but is hindered by manual processing times. We aimed to investigate the utility of a model-based variational approach in segmenting meningioma.METHODS: A database of patients with a meningioma (2007-2015) was queried for patients with a contrast-enhanced volumetric MRI, who had consented to a research tissue biobank. Manual segmentation by a neuroradiologist was performed and results were compared to the mathematical model, using a battery of tests including the Sørensen-Dice coefficient (DICE) and JACCARD index. A publicly available meningioma dataset (708 segmented T1 contrast-enhanced slices) was also used to test the reliability of the model.RESULTS: 49 meningioma cases were included. The most common meningioma location was convexity ( n = 15, 30.6%). The mathematical model segmented all but one incidental meningioma, which failed due to the lack of contrast uptake. The median meningioma volume by manual segmentation was 19.0 cm 3 (IQR 4.9-31.2). The median meningioma volume using the mathematical model was 16.9 cm 3 (IQR 4.6-28.34). The mean DICE score was 0.90 (SD = 0.04). The mean JACCARD index was 0.82 (SD = 0.07). For the publicly available dataset, the mean DICE and JACCARD scores were 0.90 (SD = 0.06) and 0.82 (SD = 0.10), respectively. CONCLUSIONS: Segmentation of meningioma volume using the proposed mathematical model was possible with accurate results. Application of this model on contrast-enhanced volumetric imaging may help reduce work burden on neuroradiologists with the increasing number in meningioma diagnoses.

AB - BACKGROUND: Meningioma is the commonest primary brain tumour. Volumetric post-contrast magnetic resonance imaging (MRI) is recognised as gold standard for delineation of meningioma volume but is hindered by manual processing times. We aimed to investigate the utility of a model-based variational approach in segmenting meningioma.METHODS: A database of patients with a meningioma (2007-2015) was queried for patients with a contrast-enhanced volumetric MRI, who had consented to a research tissue biobank. Manual segmentation by a neuroradiologist was performed and results were compared to the mathematical model, using a battery of tests including the Sørensen-Dice coefficient (DICE) and JACCARD index. A publicly available meningioma dataset (708 segmented T1 contrast-enhanced slices) was also used to test the reliability of the model.RESULTS: 49 meningioma cases were included. The most common meningioma location was convexity ( n = 15, 30.6%). The mathematical model segmented all but one incidental meningioma, which failed due to the lack of contrast uptake. The median meningioma volume by manual segmentation was 19.0 cm 3 (IQR 4.9-31.2). The median meningioma volume using the mathematical model was 16.9 cm 3 (IQR 4.6-28.34). The mean DICE score was 0.90 (SD = 0.04). The mean JACCARD index was 0.82 (SD = 0.07). For the publicly available dataset, the mean DICE and JACCARD scores were 0.90 (SD = 0.06) and 0.82 (SD = 0.10), respectively. CONCLUSIONS: Segmentation of meningioma volume using the proposed mathematical model was possible with accurate results. Application of this model on contrast-enhanced volumetric imaging may help reduce work burden on neuroradiologists with the increasing number in meningioma diagnoses.

KW - Humans

KW - Meningioma/diagnostic imaging

KW - Reproducibility of Results

KW - Image Processing, Computer-Assisted/methods

KW - Magnetic Resonance Imaging/methods

KW - Meningeal Neoplasms/diagnostic imaging

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DO - 10.1177/19714009231224442

M3 - Article

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SN - 1971-4009

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SP - 199

EP - 205

JO - The neuroradiology journal

JF - The neuroradiology journal

IS - 2

ER -

A semi-automatic segmentation method for meningioma developed using a variational approach model

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