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声带外展/内收的三维模型。

A three-dimensional model of vocal fold abduction/adduction.

作者信息

Hunter Eric J, Titze Ingo R, Alipour Fariborz

机构信息

National Center for Voice and Speech, The Denver Center for the Performing Arts, Denver, Colorado 80204, USA.

出版信息

J Acoust Soc Am. 2004 Apr;115(4):1747-59. doi: 10.1121/1.1652033.

DOI:10.1121/1.1652033
PMID:15101653
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1550351/
Abstract

A three-dimensional biomechanical model of tissue deformation was developed to simulate dynamic vocal fold abduction and adduction. The model was made of 1721 nearly incompressible finite elements. The cricoarytenoid joint was modeled as a rocking-sliding motion, similar to two concentric cylinders. The vocal ligament and the thyroarytenoid muscle's fiber characteristics were implemented as a fiber-gel composite made of an isotropic ground substance imbedded with fibers. These fibers had contractile and/or passive nonlinear stress-strain characteristics. The verification of the model was made by comparing the range and speed of motion to published vocal fold kinematic data. The model simulated abduction to a maximum glottal angle of about 31 degrees. Using the posterior-cricoarytenoid muscle, the model produced an angular abduction speed of 405 degrees per second. The system mechanics seemed to favor abduction over adduction in both peak speed and response time, even when all intrinsic muscle properties were kept identical. The model also verified the notion that the vocalis and muscularis portions of the thyroarytenoid muscle play significantly different roles in posturing, with the muscularis portion having the larger effect on arytenoid movement. Other insights into the mechanisms of abduction/adduction were given.

摘要

建立了一个组织变形的三维生物力学模型,以模拟声带的动态外展和内收。该模型由1721个几乎不可压缩的有限元组成。环杓关节被模拟为一种类似两个同心圆柱的摇摆滑动运动。声带韧带和甲杓肌的纤维特性被实现为一种由嵌入纤维的各向同性基质组成的纤维凝胶复合材料。这些纤维具有收缩和/或被动非线性应力应变特性。通过将运动范围和速度与已发表的声带运动学数据进行比较,对该模型进行了验证。该模型模拟外展至最大声门角约31度。使用后环杓肌,该模型产生的角外展速度为每秒405度。即使所有内在肌肉特性保持相同,该系统力学在峰值速度和响应时间方面似乎都更有利于外展而非内收。该模型还证实了甲杓肌的声带部分和肌部在姿势形成中发挥着显著不同的作用这一观点,其中肌部对杓状软骨运动的影响更大。还给出了关于外展/内收机制的其他见解。

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本文引用的文献

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A two-dimensional biomechanical model of vocal fold posturing.
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