基于多维信息融合的无监督快速肺部血管分割算法

doi:10.3969/j.issn.0258-8021.2023.03.005

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摘要肺部CT图像中血管的分割在疾病的诊断和外科治疗中起着重要作用。在医学图像相关任务中,深度学习因其强大的表现能力和辨别学习能力,被广泛应用。然而基于深度学习的方法需要昂贵的GPU和大量有标签的数据。为了更好地平衡肺部CT图像血管分割的准确性和效率,提出了一种基于多维信息融合的快速有效的血管分割算法(MDF),该算法设计2D分割分支和3D分割分支来充分利用2D和3D信息,在最后的分割结果中对多个分支的结果进行合并,能够快速有效地融入到传统无监督算法。与此同时,MDF具有强大并行能力,能够在低端显卡上被显著加速。选取VESSEL12挑战的23例数据以及CARVE14挑战赛的55例数据对所提出的基于多维信息融合的血管分割算法进行了全面评估。实验结果表明,MDF与其他无监督算法相比有着更高的精度,在CARVE14数据集上血管的DSC系数达到了0.716。除此之外,通过GPU并行优化,运行速度大约为基于Hession矩阵的Frangi多尺度算法的20倍。与深度学习算法相比,MDF在不同数据集上的泛化能力更强。

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	陈骅桂
	周雷
	赵廉
	丛志洋

关键词 ：血管分割, 深度学习, 多维信息融合, 并行优化

Abstract：The segmentation of vessels in lung CT images plays an important role in the diagnosis and surgical treatment of diseases. In medical image related tasks, deep learning is widely used due to their strong feature representation and discriminative learning abilities. However, deep learning-based methods requires expensive GPUs and large amount of labeled data. In order to achieve better balance between the accuracy and efficiency of vessel segmentation in lung CT images, in this paper, a faster and more effective unsupervised vessel segmentation algorithm based onmulti-dimensional information fusion (MDF) was proposed. The algorithm designed 2D segmentation branches and 3D segmentation branches to make full use of 2D and 3D information, and combined the results of multiple branches in the final segmentation results, which can be quickly and effectively integrated into the traditional unsupervised algorithm. Meanwhile, MDF has strong parallelism capability and can be significantly accelerated on GPU. The proposed MDF based vessel segmentation algorithm was evaluated on the challenging VESSEL12 dataset and CARVE14 dataset comprehensively. The experimental results showed that MDF segmented the vessels in lung CT images with higher accuracy compared with other unsupervised methods. On the CARVE14 dataset, the DSC coefficient of vessels reached 0.716. Moreover, the MDF inference speed was roughly 20 times faster than Frangi algorithms, a multiscale algorithm based on Hession matrix, by GPU parallel optimization. Compared with deep learning-based methods, the segmentation performance of MDF exhibited stronger adaptation ability.

Key words： vessel segmentation deep learning multi-dimensional information fusion performance optimization

收稿日期: 2022-03-20

PACS:

R318

基金资助:国家自然科学基金(61906121)

通讯作者: ^* E-mail: zmbhou@163.com

引用本文:

陈骅桂, 周雷, 赵廉, 丛志洋. 基于多维信息融合的无监督快速肺部血管分割算法[J]. 中国生物医学工程学报, 2023, 42(3): 289-300.
Chen Huagui, Zhou Lei, Zhao Lian, Cong Zhiyang. Faster Lung Vessel Segmentation Using Multi-Dimensional Information Fusion. Chinese Journal of Biomedical Engineering, 2023, 42(3): 289-300.

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http://cjbme.csbme.org/CN/10.3969/j.issn.0258-8021.2023.03.005 或 http://cjbme.csbme.org/CN/Y2023/V42/I3/289

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