Sensitivity of the shear wave speed-stress relationship to soft tissue material properties and fiber alignment.

Jonathon L. Blank, D. Thelen, M. Allen, J. Roth
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引用次数: 8

Abstract

The use of shear wave propagation to noninvasively measure material properties and loading in tendons and ligaments is a growing area of interest in biomechanics. Prior models and experiments suggest that shear wave speed primarily depends on the apparent shear modulus (i.e., shear modulus accounting for contributions from all constituents) at low loads, and then increases with axial stress when axially loaded. However, differences in the magnitudes of shear wave speeds between ligaments and tendons, which have different substructures, suggest that the tissue's composition and fiber alignment may also affect shear wave propagation. Accordingly, the objectives of this study were to (1) characterize changes in the apparent shear modulus induced by variations in constitutive properties and fiber alignment, and (2) determine the sensitivity of the shear wave speed-stress relationship to variations in constitutive properties and fiber alignment. To enable systematic variations of both constitutive properties and fiber alignment, we developed a finite element model that represented an isotropic ground matrix with an embedded fiber distribution. Using this model, we performed dynamic simulations of shear wave propagation at axial strains from 0% to 10%. We characterized the shear wave speed-stress relationship using a simple linear regression between shear wave speed squared and axial stress, which is based on an analytical relationship derived from a tensioned beam model. We found that predicted shear wave speeds were both in-range with shear wave speeds in previous in vivo and ex vivo studies, and strongly correlated with the axial stress (R2 = 0.99). The slope of the squared shear wave speed-axial stress relationship was highly sensitive to changes in tissue density. Both the intercept of this relationship and the apparent shear modulus were sensitive to both the shear modulus of the ground matrix and the stiffness of the fibers' toe-region when the fibers were less well-aligned to the loading direction. We also determined that the tensioned beam model overpredicted the axial tissue stress with increasing load when the model had less well-aligned fibers. This indicates that the shear wave speed increases likely in response to a load-dependent increase in the apparent shear modulus. Our findings suggest that researchers may need to consider both the material and structural properties (i.e., fiber alignment) of tendon and ligament when measuring shear wave speeds in pathological tissues or tissues with less well-aligned fibers.
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剪切波速度-应力关系对软组织材料性能和纤维排列的敏感性。
使用剪切波传播来无创地测量肌腱和韧带中的材料特性和载荷是生物力学中越来越感兴趣的领域。先前的模型和实验表明,剪切波速主要取决于低载荷下的表观剪切模量(即,考虑所有成分贡献的剪切模量),然后在轴向载荷时随轴向应力增加。然而,具有不同亚结构的韧带和肌腱之间剪切波速度大小的差异表明,组织的组成和纤维排列也可能影响剪切波的传播。因此,本研究的目的是(1)表征本构特性和纤维排列变化引起的表观剪切模量的变化,以及(2)确定剪切波速-应力关系对本构特性变化和纤维排列的敏感性。为了实现本构特性和纤维排列的系统变化,我们开发了一个有限元模型,该模型表示具有嵌入纤维分布的各向同性基底。使用该模型,我们对轴向应变从0%到10%的剪切波传播进行了动态模拟。我们使用剪切波速度平方和轴向应力之间的简单线性回归来表征剪切波速度-应力关系,该回归基于从张拉梁模型导出的分析关系。我们发现,在先前的体内和离体研究中,预测的剪切波速都在剪切波速的范围内,并且与轴向应力强相关(R2=0.99)。剪切波速-轴向应力关系的平方斜率对组织密度的变化高度敏感。当纤维与载荷方向不太一致时,这种关系的截距和表观剪切模量对基底的剪切模量和纤维趾部区域的刚度都很敏感。我们还确定,当张拉梁模型的纤维排列不太好时,随着载荷的增加,该模型高估了轴向组织应力。这表明剪切波速度的增加可能是对视剪切模量的负载相关增加的响应。我们的研究结果表明,研究人员在测量病理组织或纤维排列不太好的组织中的剪切波速时,可能需要考虑肌腱和韧带的材料和结构特性(即纤维排列)。
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