使用图神经网络对动脉方向进行尺度不变、旋转等变估计。

IF 14 1区 医学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE Medical image analysis Pub Date : 2025-04-01 Epub Date: 2025-01-15 DOI:10.1016/j.media.2025.103467
Dieuwertje Alblas , Julian Suk , Christoph Brune , Kak Khee Yeung , Jelmer M. Wolterink
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引用次数: 0

摘要

在3D医学图像中可视化的血管方向是其几何形状的重要描述符,可用于中心线提取和随后的分割、标记和可视化。血管以多种尺度和扭曲程度出现,确定血管的确切方向是一个具有挑战性的问题。最近的研究使用了3D卷积神经网络(cnn)来实现这一目的,但cnn对血管大小和方向的变化很敏感。我们提出了SIRE:一个尺度不变的旋转等变估计局部船舶方向。由于对称性的保持,它是模块化的,并且具有很强的泛化性质。SIRE由一个规格等变网格CNN (GEM-CNN)组成,该网格在多个不同尺寸的嵌套球面网格上并行运行。每个网格上的特征是相应球体内图像强度的投影。这些特征是球体固有的,结合GEM-CNN的规范等变特性,导致了SO(3)旋转等变。近似尺度不变性是通过权重共享和使用对称最大聚合函数来组合多个尺度的预测来实现的。因此,SIRE可以用任意定向的、半径不同的血管进行训练,从而推广到具有大口径和弯曲度的血管。我们使用三个包含不同规模血管的数据集来证明SIRE的有效性;血管模型库(VMR)、ASOCA冠状动脉组和内部腹主动脉瘤组(AAAs)。我们将SIRE嵌入到一个中心线跟踪器中,该跟踪器可以准确地跟踪大口径AAAs,而不管SIRE使用的是什么数据。此外,跟踪器可以使用SIRE来跟踪小口径扭曲的冠状动脉,即使只使用大口径、非扭曲的aaa进行训练。通过实验验证了该方法的旋转等变性和尺度不变性。综上所述,通过结合SO(3)和尺度对称性,SIRE可用于确定训练域外血管的方向,为三维医学图像中血管的几何分析提供了一种鲁棒且数据高效的解决方案。
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SIRE: Scale-invariant, rotation-equivariant estimation of artery orientations using graph neural networks
The orientation of a blood vessel as visualized in 3D medical images is an important descriptor of its geometry that can be used for centerline extraction and subsequent segmentation, labeling, and visualization. Blood vessels appear at multiple scales and levels of tortuosity, and determining the exact orientation of a vessel is a challenging problem. Recent works have used 3D convolutional neural networks (CNNs) for this purpose, but CNNs are sensitive to variations in vessel size and orientation. We present SIRE: a scale-invariant rotation-equivariant estimator for local vessel orientation. SIRE is modular and has strongly generalizing properties due to symmetry preservations.
SIRE consists of a gauge equivariant mesh CNN (GEM-CNN) that operates in parallel on multiple nested spherical meshes with different sizes. The features on each mesh are a projection of image intensities within the corresponding sphere. These features are intrinsic to the sphere and, in combination with the gauge equivariant properties of GEM-CNN, lead to SO(3) rotation equivariance. Approximate scale invariance is achieved by weight sharing and use of a symmetric maximum aggregation function to combine predictions at multiple scales. Hence, SIRE can be trained with arbitrarily oriented vessels with varying radii to generalize to vessels with a wide range of calibres and tortuosity.
We demonstrate the efficacy of SIRE using three datasets containing vessels of varying scales; the vascular model repository (VMR), the ASOCA coronary artery set, and an in-house set of abdominal aortic aneurysms (AAAs). We embed SIRE in a centerline tracker which accurately tracks large calibre AAAs, regardless of the data SIRE is trained with. Moreover, a tracker can use SIRE to track small-calibre tortuous coronary arteries, even when trained only with large-calibre, non-tortuous AAAs. Additional experiments are performed to verify the rotational equivariant and scale invariant properties of SIRE.
In conclusion, by incorporating SO(3) and scale symmetries, SIRE can be used to determine orientations of vessels outside of the training domain, offering a robust and data-efficient solution to geometric analysis of blood vessels in 3D medical images.
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来源期刊
Medical image analysis
Medical image analysis 工程技术-工程:生物医学
CiteScore
22.10
自引率
6.40%
发文量
309
审稿时长
6.6 months
期刊介绍: Medical Image Analysis serves as a platform for sharing new research findings in the realm of medical and biological image analysis, with a focus on applications of computer vision, virtual reality, and robotics to biomedical imaging challenges. The journal prioritizes the publication of high-quality, original papers contributing to the fundamental science of processing, analyzing, and utilizing medical and biological images. It welcomes approaches utilizing biomedical image datasets across all spatial scales, from molecular/cellular imaging to tissue/organ imaging.
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