脑皮质厚度数据的深度学习用于疾病分类

Medhani Menikdiwela, Chuong V. Nguyen, Marnie E. Shaw
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引用次数: 16

摘要

深度学习已被应用于通过体积核磁共振扫描来学习和分类脑部疾病,其准确性接近甚至超过人类专家。这通常是通过将卷积神经网络应用于3D脑图像体积的切片来完成的。然而,每块脑体积切片只代表皮质层的一小块横截面积。另一方面,卷积神经网络在3D体积上的发展并不好。因此,我们试图将深度网络应用于二维皮层表面,以对阿尔茨海默病(AD)进行分类。已知阿尔茨海默病会影响大脑皮层表面的厚度和几何形状。尽管皮质表面具有复杂的几何结构,但我们提出了一种新的数据处理方法,将整个皮质表面的信息馈送到现有的深度网络中,以更准确地进行早期疾病检测。脑三维MRI体积登记,其皮质表面被平展到二维平面。厚度、曲率和表面积的扁平分布被组合成一个RBG图像,可以很容易地馈送到现有的深度网络。本文使用脑MRI扫描的ADNI数据集,并将平面化的皮质图像应用于不同的深度网络,包括ResNet和Inception。阿尔茨海默病的两个临床前阶段被考虑;稳定型轻度认知障碍(MCIs)和转换型轻度认知障碍(MCIc)。实验表明,与使用具有相同网络结构的大脑切片相比,始终使用平坦的皮层图像具有更高的准确性。具体来说,盗梦空间使用平坦的皮质图像获得了81%的最高准确率,相比之下,相同的网络在大脑切片上获得了68%的准确率,而文献中使用深度网络在大脑切片上获得的最佳方法的准确率为75.9%。我们的研究结果表明,平坦的皮质图像可以用于AD的学习和分类,准确率很高。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Deep Learning on Brain Cortical Thickness Data for Disease Classification
Deep learning has been applied to learn and classify brain disease using volumetric MRI scans with an accuracy approaching or even exceeding that of a human expert. This is typically done by applying convolutional neural networks to slices of a 3D brain image volume. Each slice of the brain volume, however, represents only a small cross-sectional area of the cortical layer. On the other hand, convolutional neural networks are less well developed for 3D volumes. Therefore we sought to apply deep networks to the 2D cortical surface, for the purpose of classifying Alzheimer's disease (AD). AD is known to affect the thickness and geometry of the cortical surface of the brain. Although the cortical surface has a complex geometry, here we present a novel data processing method to feed the information of an entire cortical surface into existing deep networks for more accurate early disease detection. A brain 3D MRI volume is registered and its cortical surface is flattened to a 2D plane. The flattened distributions of the thickness, curvature and surface area are combined into an RBG image which can be readily fed to existing deep networks. In this paper, the ADNI dataset of brain MRI scans are used and flattened cortical images are applied to different deep networks including ResNet and Inception. Two pre-clinical stages of AD are considered; stable mild cognitive impairment (MCIs) and converting mild cognitive impairment (MCIc). Experiments show that using flattened cortical images consistently leads to higher accuracy compared to using brain slices with the same network architecture. Specifically, the highest accuracy of 81% is achieved by Inception with flattened cortical images, as compared to 68% by the same network on brain slices and 75.9% accuracy by the best method in the literature which also used a deep network on brain slices. Our results indicate that flattened cortical images can be used to learn and classify AD with high accuracy.
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