A micro-mechanical model for the fibrous tissues of vocal folds.

Alberto Terzolo, L. Bailly, Laurent Orgéas, T. Cochereau, Nathalie Henrich Bernardoni
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引用次数: 4

Abstract

Composed of collagen, elastin and muscular fibrous networks, vocal folds are soft laryngeal multi-layered tissues owning remarkable vibro-mechanical performances. However, the impact of their histological features on their overall mechanical properties still remains elusive. Thereby, this study presents a micro-mechanical hyperelastic model able to describe the 3D fibrous architecture and the surrounding matrices of the vocal-fold sublayers, and to predict their mechanical behavior. For each layer, the model parameters were identified using available histo-mechanical data, including their quasi-static response for key physiological loading paths, i.e., longitudinal tension, transverse compression and longitudinal shear. Regardless of the loading path, it is shown how macroscale nonlinear, anisotropic tissue responses are inherited from the fiber scale. Scenarios of micro-mechanisms are predicted, highlighting the major role of 3D fiber orientation in tension, steric hindrance in compression, and matrix contribution in shear. Finally, combining these predictions to vibrating hyperelastic Timoshenko beam's theory, the impact of the fibrous architecture of the upper layers on vocal-fold vibratory properties is emphasized.
声带纤维组织的微观力学模型。
声带是由胶原蛋白、弹性蛋白和肌肉纤维网络组成的喉软层组织,具有显著的振动力学性能。然而,其组织学特征对其整体力学性能的影响仍然是难以捉摸的。因此,本研究提出了一种微力学超弹性模型,能够描述声襞亚层的三维纤维结构和周围基质,并预测其力学行为。对于每一层,利用现有的组织力学数据确定模型参数,包括它们对关键生理加载路径(即纵向拉伸、横向压缩和纵向剪切)的准静态响应。无论加载路径如何,都表明了宏观尺度的非线性、各向异性组织响应是如何从纤维尺度继承的。预测了微观机制的场景,强调了三维纤维取向在拉伸中的主要作用,在压缩中的空间位阻和在剪切中的基质贡献。最后,将这些预测与振动超弹性Timoshenko梁理论相结合,强调了上层纤维结构对声带振动特性的影响。
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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