Subject Specific Sparse Dictionary Learning for Atlas based Brain MRI Segmentation.

Snehashis Roy, Aaron Carass, Jerry L Prince, Dzung L Pham
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引用次数: 78

Abstract

Quantitative measurements from segmentations of soft tissues from magnetic resonance images (MRI) of human brains provide important biomarkers for normal aging, as well as disease progression. In this paper, we propose a patch-based tissue classification method from MR images using sparse dictionary learning from an atlas. Unlike most atlas-based classification methods, deformable registration from the atlas to the subject is not required. An "atlas" consists of an MR image, its tissue probabilities, and the hard segmentation. The "subject" consists of the MR image and the corresponding affine registered atlas probabilities (or priors). A subject specific patch dictionary is created by learning relevant patches from the atlas. Then the subject patches are modeled as sparse combinations of learned atlas patches. The same sparse combination is applied to the segmentation patches of the atlas to generate tissue memberships of the subject. The novel combination of prior probabilities in the example patches enables us to distinguish tissues having similar intensities but having different spatial location. We show that our method outperforms two state-of-the-art whole brain tissue segmentation methods. We experimented on 12 subjects having manual tissue delineations, obtaining mean Dice coefficients of 0:91 and 0:87 for cortical gray matter and cerebral white matter, respectively. In addition, experiments on subjects with ventriculomegaly shows significantly better segmentation using our approach than the competing methods.

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基于Atlas的脑MRI分割的主题稀疏字典学习。
从人类大脑的磁共振图像(MRI)中对软组织的分割进行定量测量,为正常衰老和疾病进展提供了重要的生物标志物。在本文中,我们提出了一种基于补丁的MR图像组织分类方法,该方法使用了来自图谱的稀疏字典学习。与大多数基于地图集的分类方法不同,不需要从地图集到主题的可变形注册。“地图集”由MR图像、其组织概率和硬分割组成。“主体”由MR图像和相应的仿射注册图谱概率(或先验)组成。通过从地图集中学习相关补丁,创建主题特定的补丁字典。然后将主题块建模为学习到的地图集块的稀疏组合。将相同的稀疏组合应用于图集的分割补丁以生成主题的组织隶属度。样本斑块中先验概率的新颖组合使我们能够区分具有相似强度但具有不同空间位置的组织。我们表明,我们的方法优于两种最先进的全脑组织分割方法。我们对12名受试者进行了手工组织描绘,得到皮层灰质和脑白质的平均Dice系数分别为0:91和0:87。此外,对脑室肿大受试者的实验表明,使用我们的方法比竞争对手的方法有明显更好的分割。
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