School of Information and Electronics, Beijing Institute of Technology, Beijing, China.
School of Information and Electronics, Beijing Institute of Technology, Beijing, China.
Med Image Anal. 2021 Aug;72:102094. doi: 10.1016/j.media.2021.102094. Epub 2021 Apr 30.
White matter (WM) tract segmentation based on diffusion magnetic resonance imaging (dMRI) provides an important tool for the analysis of brain development, function, and disease. Deep learning based methods of WM tract segmentation have been proposed, which greatly improve the accuracy of the segmentation. However, the training of the deep networks usually requires a large number of manual delineations of WM tracts, which can be especially difficult to obtain and unavailable in many scenarios. Therefore, in this work, we explore how to perform deep learning based WM tract segmentation when annotated training data is scarce. To this end, we seek to exploit the abundant unannotated dMRI data in the self-supervised learning framework. From the unannotated data, knowledge about image context can be learned with pretext tasks that do not require manual annotations. Specifically, a deep network can be pretrained for the pretext task, and the knowledge learned from the pretext task is then transferred to the subsequent WM tract segmentation task with only a small number of annotated scans via fine-tuning. We explore two designs of pretext tasks that are related to WM tracts. The first pretext task predicts the density map of fiber streamlines, which are representations of generic WM pathways, and the training data can be obtained automatically with tractography. The second pretext task learns to mimic the results of registration-based WM tract segmentation, which, although inaccurate, is more relevant to WM tract segmentation and provides a good target for learning context knowledge. Then, we combine the two pretext tasks and develop a nested self-supervised learning strategy. In the nested self-supervised learning strategy, the first pretext task provides initial knowledge for the second pretext task, and the knowledge learned from the second pretext task with the initial knowledge is transferred to the target WM tract segmentation task via fine-tuning. To evaluate the proposed method, experiments were performed on brain dMRI scans from the Human Connectome Project dataset with various experimental settings. The results show that the proposed method improves the performance of WM tract segmentation when tract annotations are scarce.
基于弥散磁共振成像(dMRI)的白质(WM)束分割为脑发育、功能和疾病的分析提供了重要工具。已经提出了基于深度学习的 WM 束分割方法,这些方法大大提高了分割的准确性。然而,深度网络的训练通常需要大量的 WM 束手动勾画,这在许多场景中可能特别难以获得和不可用。因此,在这项工作中,我们探索了当有注释的训练数据稀缺时如何进行基于深度学习的 WM 束分割。为此,我们试图在自我监督学习框架中利用丰富的未注释的 dMRI 数据。从未注释的数据中,可以使用不需要手动注释的预定义任务学习图像上下文的知识。具体来说,可以对预定义任务进行深度网络预训练,然后通过微调,仅使用少量注释扫描将从预定义任务中学到的知识转移到后续的 WM 束分割任务中。我们探索了与 WM 束相关的两种预定义任务设计。第一个预定义任务预测纤维流线的密度图,纤维流线是通用 WM 通路的表示,并且可以通过跟踪自动获得训练数据。第二个预定义任务学习模仿基于配准的 WM 束分割的结果,虽然不准确,但与 WM 束分割更相关,并为学习上下文知识提供了良好的目标。然后,我们结合这两个预定义任务并开发了一种嵌套的自我监督学习策略。在嵌套的自我监督学习策略中,第一个预定义任务为第二个预定义任务提供初始知识,并且从第二个预定义任务用初始知识学习到的知识通过微调转移到目标 WM 束分割任务。为了评估所提出的方法,在各种实验设置下,对来自人类连接组计划数据集的脑 dMRI 扫描进行了实验。结果表明,当束注释稀缺时,所提出的方法可以提高 WM 束分割的性能。
