Literature DB >> 8061776

Mechanical stress in phonation.

I R Titze1.   

Abstract

Mechanical stress is always encountered in phonation. This includes tensile stress, shear stress, impact stress during collision, maximum active contractile stress in laryngeal muscles, inertial stress, and aerodynamic stress (pressure). Order of magnitude calculations reveal that tensile stress can reach the greatest value (near 1.0 MPa), contractile stress is next in size (near 100 kPa), and aerodynamic stress is relatively small (1-10 kPa). Inertial stress and impact stress are greater than aerodynamic stress, but less than contractile stress. Excessive collision and acceleration may be responsible for the greatest tissue damage, even though they do not account for the greatest stresses. This is because they act perpendicularly to the direction of tissue load-bearing fibers and are applied directly to mucosal tissue.

Mesh:

Year:  1994        PMID: 8061776     DOI: 10.1016/s0892-1997(05)80302-9

Source DB:  PubMed          Journal:  J Voice        ISSN: 0892-1997            Impact factor:   2.009


  40 in total

1.  A coupled sharp-interface immersed boundary-finite-element method for flow-structure interaction with application to human phonation.

Authors:  X Zheng; Q Xue; R Mittal; S Beilamowicz
Journal:  J Biomech Eng       Date:  2010-11       Impact factor: 2.097

2.  The role of finite displacements in vocal fold modeling.

Authors:  Siyuan Chang; Fang-Bao Tian; Haoxiang Luo; James F Doyle; Bernard Rousseau
Journal:  J Biomech Eng       Date:  2013-11       Impact factor: 2.097

3.  Liquid accumulation in vibrating vocal fold tissue: a simplified model based on a fluid-saturated porous solid theory.

Authors:  Chao Tao; Jack J Jiang; Lukasz Czerwonka
Journal:  J Voice       Date:  2009-08-05       Impact factor: 2.009

4.  Cervids with different vocal behavior demonstrate different viscoelastic properties of their vocal folds.

Authors:  Tobias Riede; Susan Lingle; Eric J Hunter; Ingo R Titze
Journal:  J Morphol       Date:  2010-01       Impact factor: 1.804

5.  Dynamic vibration cooperates with connective tissue growth factor to modulate stem cell behaviors.

Authors:  Zhixiang Tong; Aidan B Zerdoum; Randall L Duncan; Xinqiao Jia
Journal:  Tissue Eng Part A       Date:  2014-02-27       Impact factor: 3.845

6.  Verification of two minimally invasive methods for the estimation of the contact pressure in human vocal folds during phonation.

Authors:  Li-Jen Chen; Luc Mongeau
Journal:  J Acoust Soc Am       Date:  2011-09       Impact factor: 1.840

7.  Comparison of Vocal Vibration-Dose Measures for Potential-Damage Risk Criteria.

Authors:  Ingo R Titze; Eric J Hunter
Journal:  J Speech Lang Hear Res       Date:  2015-10       Impact factor: 2.297

8.  Magnetic resonance imaging-based measurement of internal deformation of vibrating vocal fold models.

Authors:  Cassandra J Taylor; Grayson J Tarbox; Bradley D Bolster; Neal K Bangerter; Scott L Thomson
Journal:  J Acoust Soc Am       Date:  2019-02       Impact factor: 1.840

9.  Permeability of canine vocal fold lamina propria.

Authors:  Jacob P Meyer; Anton A Kvit; Erin E Devine; Jack Jiang
Journal:  Laryngoscope       Date:  2014-12-10       Impact factor: 3.325

10.  A computational study of systemic hydration in vocal fold collision.

Authors:  Pinaki Bhattacharya; Thomas Siegmund
Journal:  Comput Methods Biomech Biomed Engin       Date:  2013-03-26       Impact factor: 1.763
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