Statistical Shape Modeling of Biventricular Anatomy with Shared Boundaries

Krithika S. Iyer, A. Morris, B. Zenger, Karthik Karnath, Benjamin A Orkild, O. Korshak, Shireen Elhabian
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引用次数: 1

Abstract

Statistical shape modeling (SSM) is a valuable and powerful tool to generate a detailed representation of complex anatomy that enables quantitative analysis and the comparison of shapes and their variations. SSM applies mathematics, statistics, and computing to parse the shape into a quantitative representation (such as correspondence points or landmarks) that will help answer various questions about the anatomical variations across the population. Complex anatomical structures have many diverse parts with varying interactions or intricate architecture. For example, the heart is a four-chambered anatomy with several shared boundaries between chambers. Coordinated and efficient contraction of the chambers of the heart is necessary to adequately perfuse end organs throughout the body. Subtle shape changes within these shared boundaries of the heart can indicate potential pathological changes that lead to uncoordinated contraction and poor end-organ perfusion. Early detection and robust quantification could provide insight into ideal treatment techniques and intervention timing. However, existing SSM approaches fall short of explicitly modeling the statistics of shared boundaries. In this paper, we present a general and flexible data-driven approach for building statistical shape models of multi-organ anatomies with shared boundaries that captures morphological and alignment changes of individual anatomies and their shared boundary surfaces throughout the population. We demonstrate the effectiveness of the proposed methods using a biventricular heart dataset by developing shape models that consistently parameterize the cardiac biventricular structure and the interventricular septum (shared boundary surface) across the population data.
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具有共享边界的双心室解剖统计形状建模
统计形状建模(SSM)是一种有价值且功能强大的工具,可以生成复杂解剖结构的详细表示,从而实现形状及其变化的定量分析和比较。SSM应用数学、统计学和计算将形状解析为定量表示(如对应点或地标),这将有助于回答关于整个人群的解剖变化的各种问题。复杂的解剖结构有许多不同的部分和不同的相互作用或复杂的结构。例如,心脏有四个腔体,腔体之间有几个共享的边界。协调和有效的心室收缩是充分灌注全身末端器官所必需的。在这些共享的心脏边界内细微的形状变化可以提示潜在的病理改变,导致不协调的收缩和终末器官灌注不良。早期检测和稳健的量化可以为理想的治疗技术和干预时机提供见解。然而,现有的SSM方法无法明确地对共享边界的统计数据进行建模。在本文中,我们提出了一种通用且灵活的数据驱动方法,用于构建具有共享边界的多器官解剖学统计形状模型,该模型可以捕获整个种群中个体解剖学及其共享边界表面的形态学和排列变化。我们使用双室心脏数据集,通过开发形状模型,一致地参数化心脏双室结构和室间隔(共享边界表面),证明了所提出方法的有效性。
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Spatiotemporal Cardiac Statistical Shape Modeling: A Data-Driven Approach. Statistical Shape Modeling of Biventricular Anatomy with Shared Boundaries. Multi-modal Latent-Space Self-alignment for Super-Resolution Cardiac MR Segmentation. An Atlas-Based Analysis of Biventricular Mechanics in Tetralogy of Fallot. Statistical shape analysis of the tricuspid valve in hypoplastic left heart sydrome.
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