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引用次数: 0

摘要

皮质厚度是神经退行性疾病中与灰质萎缩相关的重要生物标志物。为了对不同受试者的皮层厚度进行有意义的比较,必须建立表面网格之间的对应关系。传统方法通过将表面投影到典型域(如单位球面)上或平均解剖学感兴趣区(ROI)的特征值来实现这一目的。然而,由于大脑皮层地形的天然可变性,很难实现完美的解剖学意义上的一对一映射,而且平均值的做法会导致详细信息的丢失。例如,两个受试者在同一区域的回旋结构数量可能不同,因此映射可能导致回旋/丘脑不匹配,从而引入噪声和平均化,导致局部详细信息丢失。因此,有必要开发新的方法来克服这些内在问题,从而为萎缩检测构建更有意义的比较。为了解决这些局限性,我们提出了一种新颖的基于贴片的个性化方法,以改善不同受试者的皮层厚度比较。我们的模型根据脑回和脑沟结构将大脑表面分割成不同的斑块,以减少映射方法中的不匹配,同时还保留了平均化过程中可能被忽略的详细拓扑信息。此外,由于并非所有受试者都具有可比性,每个斑块的个性化模板还考虑到了折叠模式的可变性。最后,我们通过正态性评估实验证明,在检测轻度认知障碍(MCI)和阿尔茨海默病(AD)患者的萎缩方面,我们的模型比标准球形配准效果更好。
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Personalized Patch-based Normality Assessment of Brain Atrophy in Alzheimer's Disease.

Cortical thickness is an important biomarker associated with gray matter atrophy in neurodegenerative diseases. In order to conduct meaningful comparisons of cortical thickness between different subjects, it is imperative to establish correspondence among surface meshes. Conventional methods achieve this by projecting surface onto canonical domains such as the unit sphere or averaging feature values in anatomical regions of interest (ROIs). However, due to the natural variability in cortical topography, perfect anatomically meaningful one-to-one mapping can be hardly achieved and the practice of averaging leads to the loss of detailed information. For example, two subjects may have different number of gyral structures in the same region, and thus mapping can result in gyral/sulcal mismatch which introduces noise and averaging in detailed local information loss. Therefore, it is necessary to develop new method that can overcome these intrinsic problems to construct more meaningful comparison for atrophy detection. To address these limitations, we propose a novel personalized patch-based method to improve cortical thickness comparison across subjects. Our model segments the brain surface into patches based on gyral and sulcal structures to reduce mismatches in mapping method while still preserving detailed topological information which is potentially discarded in averaging. Moreover,the personalized templates for each patch account for the variability of folding patterns, as not all subjects are comparable. Finally, through normality assessment experiments, we demonstrate that our model performs better than standard spherical registration in detecting atrophy in patients with mild cognitive impairment (MCI) and Alzheimer's disease (AD).

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