DeepBundle:使用图卷积神经网络的光纤束分割。

Feihong Liu, Jun Feng, Geng Chen, Ye Wu, Yoonmi Hong, Pew-Thian Yap, Dinggang Shen
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引用次数: 14

摘要

全脑束线的分割是基于束状图分析脑白质微观结构的重要步骤。现有的纤维分割方法依赖于图谱与个体束状图之间的准确配准,但由于个体差异较大,在实际应用中难以保证准确配准。为了解决这个问题,我们提出了一种新的深度学习方法,称为DeepBundle,用于无配准光纤打包。我们的方法利用图卷积神经网络(GCNNs)来预测每个纤维束的包裹标签。gcnn能够提取每个纤维束的几何特征,并利用所得到的特征进行精确的纤维分割,最终避免使用地图集和任何配准方法。我们使用来自人类连接体项目的数据来评估DeepBundle。实验结果证明了DeepBundle的优势,并表明从每个纤维束中提取的几何特征可以有效地分割纤维束。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

DeepBundle: Fiber Bundle Parcellation with Graph Convolution Neural Networks.

DeepBundle: Fiber Bundle Parcellation with Graph Convolution Neural Networks.

DeepBundle: Fiber Bundle Parcellation with Graph Convolution Neural Networks.

Parcellation of whole-brain tractography streamlines is an important step for tract-based analysis of brain white matter microstructure. Existing fiber parcellation approaches rely on accurate registration between an atlas and the tractograms of an individual, however, due to large individual differences, accurate registration is hard to guarantee in practice. To resolve this issue, we propose a novel deep learning method, called DeepBundle, for registration-free fiber parcellation. Our method utilizes graph convolution neural networks (GCNNs) to predict the parcellation label of each fiber tract. GCNNs are capable of extracting the geometric features of each fiber tract and harnessing the resulting features for accurate fiber parcellation and ultimately avoiding the use of atlases and any registration method. We evaluate DeepBundle using data from the Human Connectome Project. Experimental results demonstrate the advantages of DeepBundle and suggest that the geometric features extracted from each fiber tract can be used to effectively parcellate the fiber tracts.

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