The Influence of Material Anisotropy on Vibration at Onset in a Three-dimensional Vocal Fold Model

Overview

Journal J Acoust Soc Am

Publisher American Institute of Physics

Specialty Otorhinolaryngology

Date 2014 Mar 11

PMID 24606284

Citations 9

Authors

Zhaoyan Zhang

Affiliations

Soon will be listed here.

Abstract

Although vocal folds are known to be anisotropic, the influence of material anisotropy on vocal fold vibration remains largely unknown. Using a linear stability analysis, phonation onset characteristics were investigated in a three-dimensional anisotropic vocal fold model. The results showed that isotropic models had a tendency to vibrate in a swing-like motion, with vibration primarily along the superior-inferior direction. Anterior-posterior (AP) out-of-phase motion was also observed and large vocal fold vibration was confined to the middle third region along the AP length. In contrast, increasing anisotropy or increasing AP-transverse stiffness ratio suppressed this swing-like motion and allowed the vocal fold to vibrate in a more wave-like motion with strong medial-lateral motion over the entire medial surface. Increasing anisotropy also suppressed the AP out-of-phase motion, allowing the vocal fold to vibrate in phase along the entire AP length. Results also showed that such improvement in vibration pattern was the most effective with large anisotropy in the cover layer alone. These numerical predictions were consistent with previous experimental observations using self-oscillating physical models. It was further hypothesized that these differences may facilitate complete glottal closure in finite-amplitude vibration of anisotropic models as observed in recent experiments.

Citing Articles

Flow-induced oscillations of vocal-fold replicas with tuned extensibility and material properties.

Luizard P, Bailly L, Yousefi-Mashouf H, Girault R, Orgeas L, Henrich Bernardoni N Sci Rep. 2023; 13(1):22658.

PMID: 38114547 PMC: 10730560. DOI: 10.1038/s41598-023-48080-x.

Bayesian Inference of Vocal Fold Material Properties from Glottal Area Waveforms Using a 2D Finite Element Model.

Hadwin P, Motie-Shirazi M, Erath B, Peterson S Appl Sci (Basel). 2021; 9(13).

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Vocal fold contact pressure in a three-dimensional body-cover phonation model.

Zhang Z J Acoust Soc Am. 2019; 146(1):256.

PMID: 31370600 PMC: 6642050. DOI: 10.1121/1.5116138.

Effect of Longitudinal Variation of Vocal Fold Inner Layer Thickness on Fluid-Structure Interaction During Voice Production.

Jiang W, Xue Q, Zheng X J Biomech Eng. 2018; 140(12).

PMID: 30098145 PMC: 6993787. DOI: 10.1115/1.4041045.

Comparison of a fiber-gel finite element model of vocal fold vibration to a transversely isotropic stiffness model.

Titze I, Alipour F, Blake D, Palaparthi A J Acoust Soc Am. 2017; 142(3):1376.

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