Abstract
Segmentation of white matter lesions and deep grey matter structures is an important task in the quantification of magnetic resonance imaging in multiple sclerosis. In this paper we explore segmentation solutions based on convolutional neural networks (CNNs) for providing fast, reliable segmentations of lesions and grey-matter structures in multi-modal MR imaging, and the performance of these methods when applied to out-of-centre data. We trained two state-of-the-art fully convolutional CNN architectures on the 2016 MSSEG training dataset, which was annotated by seven independent human raters: a reference implementation of a 3D Unet, and a more recently proposed 3D-to-2D architecture (DeepSCAN). We then retrained those methods on a larger dataset from a single centre, with and without labels for other brain structures. We quantified changes in performance owing to dataset shift, and changes in performance by adding the additional brain-structure labels. We also compared performance with freely available reference methods. Both fully-convolutional CNN methods substantially outperform other approaches in the literature when trained and evaluated in cross-validation on the MSSEG dataset, showing agreement with human raters in the range of human inter-rater variability. Both architectures showed drops in performance when trained on single-centre data and tested on the MSSEG dataset. When trained with the addition of weak anatomical labels derived from Freesurfer, the performance of the 3D Unet degraded, while the performance of the DeepSCAN net improved. Overall, the DeepSCAN network predicting both lesion and anatomical labels was the best-performing network examined.
Highlights
Segmentation of white matter lesions and deep grey matter structures is an important task in the quantification of magnetic resonance imaging in multiple sclerosis
We study modern deep learning methods performing a simultaneous segmentation of both lesions and grey matter structures, trained on a combination of lesion segmentations produced by manual raters, and weak labels for the healthy-appearing tissue provided by an existing automated method (Freesurfer)
We studied in this work the performance of convolutional neural networks (CNNs)-based lesion segmentation methods on two datasets: a small publicly available dataset, and a larger dataset from our own centre
Summary
Segmentation of white matter lesions and deep grey matter structures is an important task in the quantification of magnetic resonance imaging in multiple sclerosis. We trained two state-of-the-art fully convolutional CNN architectures on the 2016 MSSEG training dataset, which was annotated by seven independent human raters: a reference implementation of a 3D Unet, and a more recently proposed 3D-to-2D architecture (DeepSCAN) We retrained those methods on a larger dataset from a single centre, with and without labels for other brain structures. We compared performance with freely available reference methods Both fullyconvolutional CNN methods substantially outperform other approaches in the literature when trained and evaluated in cross-validation on the MSSEG dataset, showing agreement with human raters in the range of human inter-rater variability. We study modern deep learning methods performing a simultaneous segmentation of both lesions and grey matter structures, trained on a combination of lesion segmentations produced by manual raters, and weak labels for the healthy-appearing tissue provided by an existing automated method (Freesurfer). Our hypothesis is that modern deep learning architectures can simultaneously perform the tasks of lesion and anatomy segmentation, and that these methods are robust enough when applied to data outside of the training sample to distribute and use in the context of clinical studies
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