Geometric Brain Surface Network For Brain Cortical Parcellation.

Wen Zhang, Yalin Wang
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引用次数: 2

Abstract

A large number of surface-based analyses on brain imaging data adopt some specific brain atlases to better assess structural and functional changes in one or more brain regions. In these analyses, it is necessary to obtain an anatomically correct surface parcellation scheme in an individual brain by referring to the given atlas. Traditional ways to accomplish this goal are through a designed surface-based registration or hand-crafted surface features, although both of them are time-consuming. A recent deep learning approach depends on a regular spherical parameterization of the mesh, which is computationally prohibitive in some cases and may also demand further post-processing to refine the network output. Therefore, an accurate and fully-automatic cortical surface parcellation scheme directly working on the original brain surfaces would be highly advantageous. In this study, we propose an end-to-end deep brain cortical parcellation network, called DBPN. Through intrinsic and extrinsic graph convolution kernels, DBPN dynamically deciphers neighborhood graph topology around each vertex and encodes the deciphered knowledge into node features. Eventually, a non-linear mapping between the node features and parcellation labels is constructed. Our model is a two-stage deep network which contains a coarse parcellation network with a U-shape structure and a refinement network to fine-tune the coarse results. We evaluate our model in a large public dataset and our work achieves superior performance than state-of-the-art baseline methods in both accuracy and efficiency.

Abstract Image

Abstract Image

Abstract Image

脑皮质分割的几何脑表面网络。
大量基于表面的脑成像数据分析采用一些特定的脑图谱来更好地评估一个或多个脑区域的结构和功能变化。在这些分析中,有必要通过参考给定的图谱在个体大脑中获得解剖学上正确的表面包裹方案。实现这一目标的传统方法是通过设计的基于表面的配准或手工制作的表面特征,尽管这两种方法都很耗时。最近的一种深度学习方法依赖于网格的规则球面参数化,这在某些情况下在计算上是禁止的,并且可能还需要进一步的后处理来优化网络输出。因此,一个精确的、全自动的皮质表面分割方案直接作用于原始的大脑表面将是非常有利的。在这项研究中,我们提出了一个端到端的脑深部皮层包裹网络,称为DBPN。DBPN通过内在和外在的图卷积核,对每个顶点周围的邻域图拓扑进行动态解码,并将解码的知识编码为节点特征。最后,构造了节点特征与分块标签之间的非线性映射。我们的模型是一个两阶段的深度网络,它包含一个具有u形结构的粗分割网络和一个微调粗结果的细化网络。我们在大型公共数据集中评估我们的模型,我们的工作在准确性和效率方面都比最先进的基线方法取得了更好的性能。
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