Supervised learning based multimodal MRI brain tumour segmentation using texture features from supervoxels

M. Soltaninejad; G. Yang; T. Lambrou; N. Allinson; T.L. Jones; T.R. Barrick; F.A. Howe; X. Ye

doi:10.1016/j.cmpb.2018.01.003

Supervised learning based multimodal MRI brain tumour segmentation using texture features from supervoxels

M. Soltaninejad^* (Corresponding Author), G. Yang^* (Corresponding Author), T. Lambrou^* (Corresponding Author), N. Allinson^* (Corresponding Author), T.L. Jones^* (Corresponding Author), T.R. Barrick^* (Corresponding Author), F.A. Howe^* (Corresponding Author), X. Ye^* (Corresponding Author)

^*Corresponding author for this work

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

162 Citations (Scopus)

Abstract

Background
Accurate segmentation of brain tumour in magnetic resonance images (MRI) is a difficult task due to various tumour types. Using information and features from multimodal MRI including structural MRI and isotropic (p) and anisotropic (q) components derived from the diffusion tensor imaging (DTI) may result in a more accurate analysis of brain images.
Methods
We propose a novel 3D supervoxel based learning method for segmentation of tumour in multimodal MRI brain images (conventional MRI and DTI). Supervoxels are generated using the information across the multimodal MRI dataset. For each supervoxel, a variety of features including histograms of texton descriptor, calculated using a set of Gabor filters with different sizes and orientations, and first order intensity statistical features are extracted. Those features are fed into a random forests (RF) classifier to classify each supervoxel into tumour core, oedema or healthy brain tissue.
Results
The method is evaluated on two datasets: 1) Our clinical dataset: 11 multimodal images of patients and 2) BRATS 2013 clinical dataset: 30 multimodal images. For our clinical dataset, the average detection sensitivity of tumour (including tumour core and oedema) using multimodal MRI is 86% with balanced error rate (BER) 7%; while the Dice score for automatic tumour segmentation against ground truth is 0.84. The corresponding results of the BRATS 2013 dataset are 96%, 2% and 0.89, respectively.
Conclusion
The method demonstrates promising results in the segmentation of brain tumour. Adding features from multimodal MRI images can largely increase the segmentation accuracy. The method provides a close match to expert delineation across all tumour grades, leading to a faster and more reproducible method of brain tumour detection and delineation to aid patient management.

Original language	English
Pages (from-to)	69-84
Number of pages	16
Journal	Computer Methods and Programs in Biomedicine
Volume	157
Early online date	11 Jan 2018
DOIs	https://doi.org/10.1016/j.cmpb.2018.01.003
Publication status	Published - Apr 2018

Bibliographical note

This research was supported by European FP7 collaborative
Project “MyHealthAvatar” (600929) and EPSRC grant EP/L023679/1.
MRI data were obtained during the EU FP7 “eTUMOUR” project
(LSHC-CT-2004-503094)

Data Availability Statement

Supplementary material associated with this article can be
found, in the online version, at doi:10.1016/j.cmpb.2018.01.003.

Keywords

Brain tumour segmentation
Diffusion tensor imaging
Multimodal MRI
Random forests
Supervoxel
Textons

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Supervised learning based multimodal MRI brain tumour segmentation using texture features from supervoxels. / Soltaninejad, M. (Corresponding Author); Yang, G. (Corresponding Author); Lambrou, T. (Corresponding Author) et al.
In: Computer Methods and Programs in Biomedicine, Vol. 157, 04.2018, p. 69-84.

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

@article{2e48113b83cb445c876d2a1e3f2e8008,

title = "Supervised learning based multimodal MRI brain tumour segmentation using texture features from supervoxels",

abstract = "BackgroundAccurate segmentation of brain tumour in magnetic resonance images (MRI) is a difficult task due to various tumour types. Using information and features from multimodal MRI including structural MRI and isotropic (p) and anisotropic (q) components derived from the diffusion tensor imaging (DTI) may result in a more accurate analysis of brain images.MethodsWe propose a novel 3D supervoxel based learning method for segmentation of tumour in multimodal MRI brain images (conventional MRI and DTI). Supervoxels are generated using the information across the multimodal MRI dataset. For each supervoxel, a variety of features including histograms of texton descriptor, calculated using a set of Gabor filters with different sizes and orientations, and first order intensity statistical features are extracted. Those features are fed into a random forests (RF) classifier to classify each supervoxel into tumour core, oedema or healthy brain tissue.ResultsThe method is evaluated on two datasets: 1) Our clinical dataset: 11 multimodal images of patients and 2) BRATS 2013 clinical dataset: 30 multimodal images. For our clinical dataset, the average detection sensitivity of tumour (including tumour core and oedema) using multimodal MRI is 86% with balanced error rate (BER) 7%; while the Dice score for automatic tumour segmentation against ground truth is 0.84. The corresponding results of the BRATS 2013 dataset are 96%, 2% and 0.89, respectively.ConclusionThe method demonstrates promising results in the segmentation of brain tumour. Adding features from multimodal MRI images can largely increase the segmentation accuracy. The method provides a close match to expert delineation across all tumour grades, leading to a faster and more reproducible method of brain tumour detection and delineation to aid patient management.",

keywords = "Brain tumour segmentation, Diffusion tensor imaging, Multimodal MRI, Random forests, Supervoxel, Textons",

author = "M. Soltaninejad and G. Yang and T. Lambrou and N. Allinson and T.L. Jones and T.R. Barrick and F.A. Howe and X. Ye",

note = "This research was supported by European FP7 collaborative Project “MyHealthAvatar” (600929) and EPSRC grant EP/L023679/1. MRI data were obtained during the EU FP7 “eTUMOUR” project (LSHC-CT-2004-503094)",

year = "2018",

month = apr,

doi = "10.1016/j.cmpb.2018.01.003",

language = "English",

volume = "157",

pages = "69--84",

journal = "Computer Methods and Programs in Biomedicine",

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T1 - Supervised learning based multimodal MRI brain tumour segmentation using texture features from supervoxels

AU - Soltaninejad, M.

AU - Yang, G.

AU - Lambrou, T.

AU - Allinson, N.

AU - Jones, T.L.

AU - Barrick, T.R.

AU - Howe, F.A.

AU - Ye, X.

N1 - This research was supported by European FP7 collaborative Project “MyHealthAvatar” (600929) and EPSRC grant EP/L023679/1. MRI data were obtained during the EU FP7 “eTUMOUR” project (LSHC-CT-2004-503094)

PY - 2018/4

Y1 - 2018/4

N2 - BackgroundAccurate segmentation of brain tumour in magnetic resonance images (MRI) is a difficult task due to various tumour types. Using information and features from multimodal MRI including structural MRI and isotropic (p) and anisotropic (q) components derived from the diffusion tensor imaging (DTI) may result in a more accurate analysis of brain images.MethodsWe propose a novel 3D supervoxel based learning method for segmentation of tumour in multimodal MRI brain images (conventional MRI and DTI). Supervoxels are generated using the information across the multimodal MRI dataset. For each supervoxel, a variety of features including histograms of texton descriptor, calculated using a set of Gabor filters with different sizes and orientations, and first order intensity statistical features are extracted. Those features are fed into a random forests (RF) classifier to classify each supervoxel into tumour core, oedema or healthy brain tissue.ResultsThe method is evaluated on two datasets: 1) Our clinical dataset: 11 multimodal images of patients and 2) BRATS 2013 clinical dataset: 30 multimodal images. For our clinical dataset, the average detection sensitivity of tumour (including tumour core and oedema) using multimodal MRI is 86% with balanced error rate (BER) 7%; while the Dice score for automatic tumour segmentation against ground truth is 0.84. The corresponding results of the BRATS 2013 dataset are 96%, 2% and 0.89, respectively.ConclusionThe method demonstrates promising results in the segmentation of brain tumour. Adding features from multimodal MRI images can largely increase the segmentation accuracy. The method provides a close match to expert delineation across all tumour grades, leading to a faster and more reproducible method of brain tumour detection and delineation to aid patient management.

AB - BackgroundAccurate segmentation of brain tumour in magnetic resonance images (MRI) is a difficult task due to various tumour types. Using information and features from multimodal MRI including structural MRI and isotropic (p) and anisotropic (q) components derived from the diffusion tensor imaging (DTI) may result in a more accurate analysis of brain images.MethodsWe propose a novel 3D supervoxel based learning method for segmentation of tumour in multimodal MRI brain images (conventional MRI and DTI). Supervoxels are generated using the information across the multimodal MRI dataset. For each supervoxel, a variety of features including histograms of texton descriptor, calculated using a set of Gabor filters with different sizes and orientations, and first order intensity statistical features are extracted. Those features are fed into a random forests (RF) classifier to classify each supervoxel into tumour core, oedema or healthy brain tissue.ResultsThe method is evaluated on two datasets: 1) Our clinical dataset: 11 multimodal images of patients and 2) BRATS 2013 clinical dataset: 30 multimodal images. For our clinical dataset, the average detection sensitivity of tumour (including tumour core and oedema) using multimodal MRI is 86% with balanced error rate (BER) 7%; while the Dice score for automatic tumour segmentation against ground truth is 0.84. The corresponding results of the BRATS 2013 dataset are 96%, 2% and 0.89, respectively.ConclusionThe method demonstrates promising results in the segmentation of brain tumour. Adding features from multimodal MRI images can largely increase the segmentation accuracy. The method provides a close match to expert delineation across all tumour grades, leading to a faster and more reproducible method of brain tumour detection and delineation to aid patient management.

KW - Brain tumour segmentation

KW - Diffusion tensor imaging

KW - Multimodal MRI

KW - Random forests

KW - Supervoxel

KW - Textons

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DO - 10.1016/j.cmpb.2018.01.003

M3 - Article

SN - 0169-2607

VL - 157

SP - 69

EP - 84

JO - Computer Methods and Programs in Biomedicine

JF - Computer Methods and Programs in Biomedicine

ER -

Supervised learning based multimodal MRI brain tumour segmentation using texture features from supervoxels

Abstract

Bibliographical note

Data Availability Statement

Keywords

Access to Document

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Cite this