Motion Estimation with Finite-Element Biomechanical Models and Tracking Constraints from Tagged MRI.

Computational biomechanics for medicine. From algorithms to models and applications Pub Date : 2017-05-01 DOI:10.1007/978-3-319-54481-6_7

Arnold David Gomez, Fanxu Xing, Deva Chan, Dzung Pham, Philip Bayly, Jerry Prince

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引用次数: 10

Abstract

Noninvasive measurements of tissue deformation provide bio-mechanical insights of an organ, which can be used as clinical functional biomarkers or experimental data for validating computational simulations. However, acquisition of 3D displacement information is susceptible to experimental inconsistency and limited scan time. In this research, we describe the process of tracking tagged magnetic resonance imaging (MRI) as enforcing harmonic phase conservation in finite-element (FE) models. This concept is demonstrated as a tool for motion estimation in a brain motion phantom, the heart, and the tongue. Our results demonstrate that the new methodology offers robustness to edge and large-displacement artifacts, and that it can be seamlessly coupled with numerical simulations for estimating fiber stretch in residually stressed tissue, or for inverse identification of muscle activation.

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基于有限元生物力学模型和标记MRI跟踪约束的运动估计。

组织变形的无创测量提供了器官的生物力学见解，可以用作临床功能生物标志物或验证计算模拟的实验数据。然而，三维位移信息的获取容易受到实验不一致和扫描时间的限制。在这项研究中，我们描述了跟踪标记磁共振成像(MRI)的过程，在有限元(FE)模型中强制执行谐波相位守恒。这个概念被证明是一个运动估计的工具，在大脑运动幻影，心脏和舌头。我们的研究结果表明，新方法对边缘和大位移伪像具有鲁棒性，并且可以无缝地与数值模拟相结合，用于估计残余应力组织中的纤维拉伸，或用于肌肉激活的反向识别。

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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Computational biomechanics for medicine. From algorithms to models and applications

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