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Journal of the Association for Research in Otolaryngology

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01.10.2015 | Research Article

Finite-Element Modelling of the Response of the Gerbil Middle Ear to Sound

verfasst von: Nima Maftoon, W. Robert J. Funnell, Sam J. Daniel, Willem F. Decraemer

Erschienen in: Journal of the Association for Research in Otolaryngology | Ausgabe 5/2015

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Abstract

We present a finite-element model of the gerbil middle ear that, using a set of baseline parameters based primarily on a priori estimates from the literature, generates responses that are comparable with responses we measured in vivo using multi-point vibrometry and with those measured by other groups. We investigated the similarity of numerous features (umbo, pars-flaccida and pars-tensa displacement magnitudes, the resonance frequency and break-up frequency, etc.) in the experimental responses with corresponding ones in the model responses, as opposed to simply computing frequency-by-frequency differences between experimental and model responses. The umbo response of the model is within the range of variability seen in the experimental data in terms of the low-frequency (i.e., well below the middle-ear resonance) magnitude and phase, the main resonance frequency and magnitude, and the roll-off slope and irregularities in the response above the resonance frequency, but is somewhat high for frequencies above the resonance frequency. At low frequencies, the ossicular axis of rotation of the model appears to correspond to the anatomical axis but the behaviour is more complex at high frequencies (i.e., above the pars-tensa break-up). The behaviour of the pars tensa in the model is similar to what is observed experimentally in terms of magnitudes, phases, the break-up frequency of the spatial vibration pattern, and the bandwidths of the high-frequency response features. A sensitivity analysis showed that the parameters that have the strongest effects on the model results are the Young’s modulus, thickness and density of the pars tensa; the Young’s modulus of the stapedial annular ligament; and the Young’s modulus and density of the malleus. Displacements of the tympanic membrane and manubrium and the low-frequency displacement of the stapes did not show large changes when the material properties of the incus, stapes, incudomallear joint, incudostapedial joint, and posterior incudal ligament were changed by ±10 % from their values in the baseline parameter set.

http://audilab.bme.mcgill.ca/AudiLab/sw/

http://code-aster.org/

In the previous gerbil model from our group (Elkhouri et al. 2006), based on magnetic-resonance-microscopy images, the inferior part of the manubrium was narrower than it should have been.

Instead of this bony attachment, Elkhouri et al. (2006) used a ligament to connect the malleus to the cavity wall.

In the model by Elkhouri et al. (2006), this ligament was considered to be composed of two bundles.

In the model of Elkhouri et al. (2006) the stapedial annular ligament was modelled by shell elements and the rotational degrees of freedom of its nodes were fixed by mistake. That boundary condition allowed only piston-like motion of the stapes.

Note that their Figure 3, also used by Volandri et al. (2011), neglects the subepidermal and submucosal connective-tissue layers that lie lateral and medial to the radial and circular fibre layers (Lim 1970).

The very high value of 20 GPa reported in Table 3 of Volandri et al. (2011) was a typographical error (GPa rather than MPa) in the original paper by Gentil et al. (2005) (personal communication with Gentil). The very low value of 1.5 MPa used by Lesser and Williams (1988) was for a 2-D model. The very low values used by Funnell and Laszlo (1978) and Funnell (2001) for E _c were intended to be extreme examples of anisotropy, not realistic estimates. The very low values used by Ferrazzini (2003) were for a pars-tensa model that was overly thick and was not smooth.

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Titel: Finite-Element Modelling of the Response of the Gerbil Middle Ear to Sound
verfasst von: Nima Maftoon
W. Robert J. Funnell
Sam J. Daniel
Willem F. Decraemer
Publikationsdatum: 01.10.2015
Verlag: Springer US
Erschienen in: Journal of the Association for Research in Otolaryngology / Ausgabe 5/2015
Print ISSN: 1525-3961
Elektronische ISSN: 1438-7573
DOI: https://doi.org/10.1007/s10162-015-0531-y

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Finite-Element Modelling of the Response of the Gerbil Middle Ear to Sound

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