Decoupling Uniaxial Tensile Prestress and Waveguide Effects From Estimates of the Complex Shear Modulus in a Cylindrical Structure Using Transverse-Polarized Dynamic Elastography.

Melika Salehabadi, Joseph Crutison, Dieter Klatt, Thomas J Royston
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Abstract

Dynamic elastography, whether based on magnetic resonance, ultrasound, or optical modalities, attempts to reconstruct quantitative maps of the viscoelastic properties of biological tissue, properties altered by disease and injury, by noninvasively measuring mechanical wave motion in the tissue. Most reconstruction strategies that have been developed neglect boundary conditions, including quasi-static tensile or compressive loading resulting in a nonzero prestress. Significant prestress is inherent to the functional role of some biological tissues currently being studied using elastography, such as skeletal and cardiac muscle, arterial walls, and the cornea. In the present article a configuration, inspired by muscle elastography but generalizable to other applications, is analytically and experimentally studied. A hyperelastic polymer phantom cylinder is statically elongated in the axial direction while its response to transverse-polarized vibratory excitation is measured. We examine the interplay between uniaxial prestress and waveguide effects in this muscle-like tissue phantom using computational finite element simulations and magnetic resonance elastography measurements. Finite deformations caused by prestress coupled with waveguide effects lead to results that are predicted by a coordinate transformation approach that has been previously used to simplify reconstruction of anisotropic properties using elastography. Here, the approach estimates material viscoelastic properties that are independent of the nonhomogeneous prestress conditions without requiring advanced knowledge of those stress conditions.

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利用横向极化动态弹性图从圆柱结构的复合剪切模量估计中解耦单轴拉伸预应力和波导效应。
动态弹性成像,无论是基于磁共振、超声还是光学模式,都试图通过无创测量组织中的机械波运动来重建生物组织粘弹性特性的定量图,这些特性因疾病和损伤而改变。大多数已经开发的重建策略忽略了边界条件,包括导致非零预应力的准静态拉伸或压缩加载。重要的预应力是固有的一些生物组织的功能作用,目前正在研究使用弹性成像,如骨骼肌和心肌,动脉壁和角膜。在本文中,一种构型,灵感来自肌肉弹性,但可推广到其他应用,是分析和实验研究。研究了超弹性聚合物模体在轴向上的静态拉伸,并测量了其对横向极化振动激励的响应。我们使用计算有限元模拟和磁共振弹性测量来研究这种肌肉样组织幻影中单轴预应力和波导效应之间的相互作用。由预应力和波导效应引起的有限变形导致的结果可以通过坐标变换方法预测,该方法先前用于简化弹性成像的各向异性特性重建。在这里,该方法估计了材料的粘弹性特性,这些特性与非均匀预应力条件无关,而不需要对这些应力条件有深入的了解。
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