基于双向树长短时记忆网络的冠状动脉自动解剖标记

Automated anatomical labeling of coronary arteries via bidirectional tree LSTMs.

机构信息

CuraCloud Corporation, 999 3rd Ave, Ste 700, Seattle, WA, 98004, USA.

School of Biomedical Engineering, Sun Yat-Sen University, Guangzhou, Guangdong, China.

出版信息

Int J Comput Assist Radiol Surg. 2019 Feb;14(2):271-280. doi: 10.1007/s11548-018-1884-6. Epub 2018 Nov 27.

DOI:10.1007/s11548-018-1884-6

PMID:30484116

Abstract

PURPOSE

Automated anatomical labeling facilitates the diagnostic process for physicians and radiologists. One of the challenges in automated anatomical labeling problems is the robustness to handle the large individual variability inherited in human anatomy. A novel deep neural network framework, referred to Tree Labeling Network (TreeLab-Net), is proposed to resolve this problem in this work.

METHODS

A multi-layer perceptron (MLP) encoder network and a bidirectional tree-structural long short-term memory (Bi-TreeLSTM) are combined to construct the TreeLab-Net. Vessel spatial locations and directions are selected as features, where a spherical coordinate transform is utilized to normalize vessel spatial variations. The dataset includes 436 coronary computed tomography angiography images. Tenfold cross-validation is performed for evaluation.

RESULTS

The precision-recall curve of TreeLab-Net shows that the four main branch classes, LM, LAD, LCX and RCA, have the area under the curve (AUC) higher than 97%. Other major side branch classes, D, OM, and R-PLB, also have AUC higher than 90%. Comparing with four other methods (i.e., AdaBoost, MLP, Up-to-Down and Down-to-Up TreeLSTM), the TreeLab-Net achieves higher F1 scores with less topological errors.

CONCLUSION

The TreeLab-Net is able to capture the characteristics of tree structures by learning the spatial and topological dependencies of blood vessels effectively. The results demonstrate that TreeLab-Net is able to yield competitive performances on a large dataset with great variance among subjects.

摘要

目的

自动化解剖学标注有助于医生和放射科医生进行诊断。在自动化解剖学标注问题中，一个挑战是具有鲁棒性，以处理人类解剖学中固有的个体变异性。在这项工作中，提出了一种新的深度神经网络框架，称为树标注网络（TreeLab-Net），以解决这个问题。

方法

多层感知机（MLP）编码器网络和双向树结构长短期记忆（Bi-TreeLSTM）相结合，构建 TreeLab-Net。选择血管空间位置和方向作为特征，其中利用球坐标变换对血管空间变化进行归一化。该数据集包括 436 例冠状动脉计算机断层血管造影图像。采用十折交叉验证进行评估。

结果

TreeLab-Net 的精度-召回曲线表明，LM、LAD、LCX 和 RCA 这四个主要分支类别的曲线下面积（AUC）均高于 97%。其他主要侧支类别，如 D、OM 和 R-PLB，AUC 也高于 90%。与其他四种方法（即 AdaBoost、MLP、Up-to-Down 和 Down-to-Up TreeLSTM）相比，TreeLab-Net 的 F1 评分更高，拓扑错误更少。

结论

TreeLab-Net 通过有效地学习血管的空间和拓扑依赖性，能够捕捉树结构的特征。结果表明，TreeLab-Net 能够在具有很大个体差异的大型数据集上获得有竞争力的性能。

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本文引用的文献

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基于双向树长短时记忆网络的冠状动脉自动解剖标记

Automated anatomical labeling of coronary arteries via bidirectional tree LSTMs.

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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