3D cardiac shape analysis with variational point cloud autoencoders for myocardial infarction prediction and virtual heart synthesis

IF 4.9 2区医学 Q1 ENGINEERING, BIOMEDICAL

Computerized Medical Imaging and Graphics Pub Date : 2025-06-19 DOI:10.1016/j.compmedimag.2025.102587

Marcel Beetz , Abhirup Banerjee , Lei Li , Julia Camps , Blanca Rodriguez , Vicente Grau

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引用次数: 0

Abstract

Cardiac anatomy and physiology vary considerably across the human population. Understanding and taking into account this variability is crucial for both accurate clinical decision-making and realistic in silico modeling of cardiac function. In this work, we propose multi-class variational point cloud autoencoders (Point VAE) as a novel geometric deep learning approach for 3D cardiac shape and function analysis. Its encoder–decoder architecture enables efficient multi-scale feature learning directly on high resolution point cloud representations of the multi-class 3D cardiac anatomy and can capture complex non-linear 3D shape variability in a low-dimensional and interpretable latent space. We first evaluate the Point VAE’s reconstruction ability on a dataset of over 10,000 subjects and find mean Chamfer distances between input and reconstructed point clouds below the pixel resolution of the underlying image acquisitions. Furthermore, we analyze the Point VAE’s latent space and observe a realistic and disentangled representation of morphological and functional variability. We test the latent space for pathology prediction and find it to outperform clinical benchmarks by 13% and 16% in area under the receiver operating characteristic (AUROC) curves for the tasks of prevalent myocardial infarction (MI) detection and incident MI prediction, respectively, and by 10% in terms of Harrell’s concordance index for MI survival analysis. Finally, we use the generated populations for in silico simulations of cardiac electrophysiology, demonstrating its ability to introduce realistic natural variability.

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用变分点云自编码器进行心肌梗死预测和虚拟心脏合成的三维心脏形状分析

不同人群的心脏解剖和生理差异很大。理解和考虑这种可变性对于准确的临床决策和心功能的现实计算机建模至关重要。在这项工作中，我们提出了多类变分点云自编码器（point VAE）作为一种新的三维心脏形状和功能分析的几何深度学习方法。其编码器-解码器架构可以直接在多类3D心脏解剖的高分辨率点云表示上进行高效的多尺度特征学习，并可以在低维和可解释的潜在空间中捕获复杂的非线性3D形状变化。我们首先在超过10,000个受试者的数据集上评估了点VAE的重建能力，并发现输入和重建点云之间的平均倒角距离低于底层图像采集的像素分辨率。此外，我们还分析了点VAE的潜在空间，并观察到形态和功能变异的真实而清晰的表现。我们测试了病理预测的潜在空间，发现在流行心肌梗死（MI）检测和事件心肌梗死预测任务的受试者工作特征（AUROC）曲线下的面积分别比临床基准高出13%和16%，在心肌梗死生存分析的Harrell一致性指数方面高出10%。最后，我们将生成的种群用于心脏电生理的计算机模拟，证明其能够引入现实的自然变异性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Computerized Medical Imaging and Graphics 医学-核医学

CiteScore

10.70

自引率

3.50%

发文量

审稿时长

26 days

期刊介绍： The purpose of the journal Computerized Medical Imaging and Graphics is to act as a source for the exchange of research results concerning algorithmic advances, development, and application of digital imaging in disease detection, diagnosis, intervention, prevention, precision medicine, and population health. Included in the journal will be articles on novel computerized imaging or visualization techniques, including artificial intelligence and machine learning, augmented reality for surgical planning and guidance, big biomedical data visualization, computer-aided diagnosis, computerized-robotic surgery, image-guided therapy, imaging scanning and reconstruction, mobile and tele-imaging, radiomics, and imaging integration and modeling with other information relevant to digital health. The types of biomedical imaging include: magnetic resonance, computed tomography, ultrasound, nuclear medicine, X-ray, microwave, optical and multi-photon microscopy, video and sensory imaging, and the convergence of biomedical images with other non-imaging datasets.