Brain ventricle parcellation using a deep neural network: Application to patients with ventriculomegaly

IF 3.4 2区医学 Q2 NEUROIMAGING

Neuroimage-Clinical Pub Date : 2019-01-01 DOI:10.1016/j.nicl.2019.101871

Muhan Shao , Shuo Han , Aaron Carass , Xiang Li , Ari M. Blitz , Jaehoon Shin , Jerry L. Prince , Lotta M. Ellingsen

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引用次数: 31

Abstract

Numerous brain disorders are associated with ventriculomegaly, including both neuro-degenerative diseases and cerebrospinal fluid disorders. Detailed evaluation of the ventricular system is important for these conditions to help understand the pathogenesis of ventricular enlargement and elucidate novel patterns of ventriculomegaly that can be associated with different diseases. One such disease is normal pressure hydrocephalus (NPH), a chronic form of hydrocephalus in older adults that causes dementia. Automatic parcellation of the ventricular system into its sub-compartments in patients with ventriculomegaly is quite challenging due to the large variation of the ventricle shape and size. Conventional brain labeling methods are time-consuming and often fail to identify the boundaries of the enlarged ventricles. We propose a modified 3D U-Net method to perform accurate ventricular parcellation, even with grossly enlarged ventricles, from magnetic resonance images (MRIs). We validated our method on a data set of healthy controls as well as a cohort of 95 patients with NPH with mild to severe ventriculomegaly and compared with several state-of-the-art segmentation methods. On the healthy data set, the proposed network achieved mean Dice similarity coefficient (DSC) of 0.895 ± 0.03 for the ventricular system. On the NPH data set, we achieved mean DSC of 0.973 ± 0.02, which is significantly (p < 0.005) higher than four state-of-the-art segmentation methods we compared with. Furthermore, the typical processing time on CPU-base implementation of the proposed method is 2 min, which is much lower than the several hours required by the other methods. Results indicate that our method provides: 1) highly robust parcellation of the ventricular system that is comparable in accuracy to state-of-the-art methods on healthy controls; 2) greater robustness and significantly more accurate results on cases of ventricular enlargement; and 3) a tool that enables computation of novel imaging biomarkers for dilated ventricular spaces that characterize the ventricular system.

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使用深度神经网络进行脑室分割：在脑室肥大患者中的应用。

许多脑部疾病与脑室肥大有关，包括神经退行性疾病和脑脊液疾病。对心室系统的详细评估对于这些情况很重要，有助于了解心室增大的发病机制，并阐明可能与不同疾病相关的心室肥大的新模式。其中一种疾病是常压脑积水（NPH），这是一种老年人的慢性脑积水，会导致痴呆。由于心室形状和大小的巨大变化，心室肥大患者的心室系统自动划分为其子室是非常具有挑战性的。传统的大脑标记方法很耗时，而且往往无法识别扩大心室的边界。我们提出了一种改进的3D U-Net方法，即使在心室严重增大的情况下，也可以从磁共振图像（MRI）中进行精确的心室分割。我们在健康对照的数据集以及95名患有轻度至重度心室肥大的NPH患者的队列中验证了我们的方法，并与几种最先进的分割方法进行了比较。在健康数据集上，所提出的网络实现了0.895的平均Dice相似系数（DSC） ± 心室系统为0.03。在NPH数据集上，我们获得了0.973的平均DSC ± 0.02，这是显著的（p

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来源期刊

Neuroimage-Clinical NEUROIMAGING-

CiteScore

7.50

自引率

4.80%

发文量

368

审稿时长

52 days

期刊介绍： NeuroImage: Clinical, a journal of diseases, disorders and syndromes involving the Nervous System, provides a vehicle for communicating important advances in the study of abnormal structure-function relationships of the human nervous system based on imaging. The focus of NeuroImage: Clinical is on defining changes to the brain associated with primary neurologic and psychiatric diseases and disorders of the nervous system as well as behavioral syndromes and developmental conditions. The main criterion for judging papers is the extent of scientific advancement in the understanding of the pathophysiologic mechanisms of diseases and disorders, in identification of functional models that link clinical signs and symptoms with brain function and in the creation of image based tools applicable to a broad range of clinical needs including diagnosis, monitoring and tracking of illness, predicting therapeutic response and development of new treatments. Papers dealing with structure and function in animal models will also be considered if they reveal mechanisms that can be readily translated to human conditions.