3D-FV-FE Aeroacoustic Larynx Model for Investigation of Functional Based Voice Disorders

Overview

Journal Front Physiol

Date 2021 Mar 25

PMID 33762964

Citations 12

Authors

Sebastian Falk

Stefan Kniesburges

Stefan Schoder

Bernhard Jakubass

Paul Maurerlehner

Matthias Echternach

Manfred Kaltenbacher

Michael Dollinger

Affiliations

Soon will be listed here.

Abstract

For the clinical analysis of underlying mechanisms of voice disorders, we developed a numerical aeroacoustic larynx model, called , that mimics commonly observed functional laryngeal disorders as glottal insufficiency and vibrational left-right asymmetries. The model is a combination of the Finite Volume (FV) CFD solver Star-CCM+ and the Finite Element (FE) aeroacoustic solver CFS++. models turbulence using Large Eddy Simulations (LES) and the acoustic wave propagation with the perturbed convective wave equation (PCWE). Its geometry corresponds to a simplified larynx and a vocal tract model representing the vowel /a/. The oscillations of the vocal folds are externally driven. In total, 10 configurations with different degrees of functional-based disorders were simulated and analyzed. The energy transfer between the glottal airflow and the vocal folds decreases with an increasing glottal insufficiency and potentially reflects the higher effort during speech for patients being concerned. This loss of energy transfer may also have an essential influence on the quality of the sound signal as expressed by decreasing sound pressure level (SPL), Cepstral Peak Prominence (CPP), and Vocal Efficiency (VE). Asymmetry in the vocal fold oscillations also reduces the quality of the sound signal. However, confirmed previous clinical and experimental observations that a high level of glottal insufficiency worsens the acoustic signal quality more than oscillatory left-right asymmetry. Both symptoms in combination will further reduce the quality of the sound signal. In summary, allows for detailed analysis of the origins of disordered voice production and hence fosters the further understanding of laryngeal physiology, including occurring dependencies. A current walltime of 10 h/cycle is, with a prospective increase in computing power, auspicious for a future clinical use of .

Citing Articles

Influence of flow rate and fiber tension on dynamical, mechanical and acoustical parameters in a synthetic larynx model with integrated fibers.

Guhring L, Tur B, Semmler M, Schutzenberger A, Kniesburges S Front Physiol. 2024; 15:1455360.

PMID: 39628941 PMC: 11611813. DOI: 10.3389/fphys.2024.1455360.

Synthetic, self-oscillating vocal fold models for voice production researcha).

Thomson S J Acoust Soc Am. 2024; 156(2):1283-1308.

PMID: 39172710 PMC: 11348498. DOI: 10.1121/10.0028267.

Neural network-based estimation of biomechanical vocal fold parameters.

Donhauser J, Tur B, Dollinger M Front Physiol. 2024; 15:1282574.

PMID: 38449783 PMC: 10916882. DOI: 10.3389/fphys.2024.1282574.

Restraining vocal fold vertical motion reduces source-filter interaction in a two-mass model.

Yoshinaga T, Zhang Z, Iida A JASA Express Lett. 2024; 4(3).

PMID: 38426891 PMC: 10926109. DOI: 10.1121/10.0025124.

On the Alignment of Acoustic and Coupled Mechanic-Acoustic Eigenmodes in Phonation by Supraglottal Duct Variations.

Kraxberger F, Nager C, Laudato M, Sundstrom E, Becker S, Mihaescu M Bioengineering (Basel). 2023; 10(12).

PMID: 38135960 PMC: 10740796. DOI: 10.3390/bioengineering10121369.

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