The anisotropic hyperelastic biomechanical response of the vocal ligament and implications for frequency regulation: A case study

Kelleher, Jordan E.; Siegmund, Thomas; Du, Mindy; Naseri, Elhum; Chan, Roger W.

doi:10.1121/1.4776204

Cited by 18 publications

(25 citation statements)

References 41 publications

(56 reference statements)

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“…The inhomogeneous composition provides a basis for anisotropic behaviour of labia, i.e. the labial layers cause a direction-dependent stress response to deformation, which is likely to facilitate the production of frequencies within the range in stereotyped fashion [33]. Stereotypy of song may constitute an important sexually selected feature [34,35], and the make-up of the labia influences the potential for maintaining a given frequency and for generating precise continuous sweeps of a wide frequency range.…”

Section: Discussionmentioning

confidence: 99%

Morphological basis for the evolution of acoustic diversity in oscine songbirds

Riede

Goller

2014

Proc. R. Soc. B.

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Acoustic properties of vocalizations arise through the interplay of neural control with the morphology and biomechanics of the sound generating organ, but in songbirds it is assumed that the main driver of acoustic diversity is variation in telencephalic motor control. Here we show, however, that variation in the composition of the vibrating tissues, the labia, underlies diversity in one acoustic parameter, fundamental frequency (F0) range. Lateral asymmetry and arrangement of fibrous proteins in the labia into distinct layers is correlated with expanded F0 range of species. The composition of the vibrating tissues thus represents an important morphological foundation for the generation of a broad F0 range, indicating that morphological specialization lays the foundation for the evolution of complex acoustic repertoires.

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Section: Discussionmentioning

confidence: 99%

Morphological basis for the evolution of acoustic diversity in oscine songbirds

Riede

Goller

2014

Proc. R. Soc. B.

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“…The stress–strain relationship in physiological VFs is typically hyperelastic (Kelleher et al, 2013a). In contrast the constitutive behavior of the physical replica and the computation model used here is linear elastic.…”

Section: Discussionmentioning

confidence: 99%

Validation of a flow–structure-interaction computation model of phonation

Bhattacharya

Siegmund

2014

Journal of Fluids and Structures

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Computational models of vocal fold (VF) vibration are becoming increasingly sophisticated, their utility currently transiting from exploratory research to predictive research. However, validation of such models has remained largely qualitative, raising questions over their applicability to interpret clinical situations. In this paper, a computational model with a segregated implementation is detailed. The model is used to predict the fluid–structure interaction (FSI) observed in a physical replica of the VFs when it is excited by airflow. Detailed quantitative comparisons are provided between the computational model and the corresponding experiment. First, the flow model is separately validated in the absence of VF motion. Then, in the presence of flow-induced VF motion, comparisons are made of the flow pressure on the VF walls and of the resulting VF displacements. Self-similarity of spatial distributions of flow pressure and VF displacements is highlighted. The self-similarity leads to normalized pressure and displacement profiles. It is shown that by using linear superposition of average and fluctuation components of normalized computed displacements, it is possible to determine displacements in the physical VF replica over a range of VF vibration conditions. Mechanical stresses in the VF interior are related to the VF displacements, thereby the computational model can also determine VF stresses over a range of phonation conditions.

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“…The variations of physical properties, such as stiffness and fracture toughness, along the anterior-posterior direction are dictated by the tissue microstructure 3, 10 . An organization of elastic fibers, such as elastin and collagen, provides tissue stiffness and its extent of deformation 10 .…”

Section: Discussion and Concluding Remarksmentioning

confidence: 99%

“…An organization of elastic fibers, such as elastin and collagen, provides tissue stiffness and its extent of deformation 10 . In contrary, high-damping extracellular matrix components, such as hyaluronic acids and glyco-samino-glycans, mainly contribute to tissue flexibility.…”

Section: Discussion and Concluding Remarksmentioning

confidence: 99%

“…The difference between the toughness values of coronal and transverse slicing highlights the tissue anisotropy and the contribution of collagen fibrils (see Miri et al 7 ). The longitudinal direction has the strongest stiffness compared to other directions because of the spatial orientation of collagen fibrils 3, 10 . Therefore, tissue exhibits its highest toughness when sliced in the coronal plane.…”

Section: Discussion and Concluding Remarksmentioning

confidence: 99%

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Fracture Toughness of Vocal Fold Tissue: A Preliminary Study

et al. 2016

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A customized mechanical tester that slices thin, soft samples was utilized to measure fracture toughness of vocal fold tissue. Porcine vocal fold lamina propria was subjected to quasi-static, guillotine-like tests at three equally distanced regions along the anterior-posterior direction. The central one-third where high-velocity collisions between vocal folds occur was found to have the maximum fracture toughness. In contrast, the anterior one-third featured a lower toughness. Fracture toughness can be indicative of the risk of benign and malignant lesions in vocal fold tissue.

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The anisotropic hyperelastic biomechanical response of the vocal ligament and implications for frequency regulation: A case study

Cited by 18 publications

References 41 publications

Morphological basis for the evolution of acoustic diversity in oscine songbirds

Morphological basis for the evolution of acoustic diversity in oscine songbirds

Validation of a flow–structure-interaction computation model of phonation

Fracture Toughness of Vocal Fold Tissue: A Preliminary Study

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