3D Finite Element Modeling of Blast Wave Transmission from the External Ear to Cochlea

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Annals of Biomedical Engineering ( 2020) https://doi.org/10.1007/s10439-020-02612-y

Original Article

3D Finite Element Modeling of Blast Wave Transmission from the External Ear to Cochlea MARCUS A. BROWN,1 XIAO D. JI,1 and RONG Z. GAN

1,2

1

School of Aerospace and Mechanical Engineering, University of Oklahoma, Norman, OK, USA; and 2School of Aerospace and Mechanical Engineering, University of Oklahoma, 865 Asp Avenue, Room 200, Norman, OK 73019, USA (Received 3 June 2020; accepted 2 September 2020) Associate Editor Estefanı´ a Pen˜a oversaw the review of this article.

Abstract—As an organ that is sensitive to pressure changes, the ear is often damaged when a person is subjected to blast exposures resulting in hearing loss due to tissue damage in the middle ear and cochlea. While observation of middle ear damage is non-invasive, examining the damage to the cochlea is difﬁcult to quantify. Previous works have modeled the cochlear response often when subjected to an acoustic pressure input, but the inner ear mechanics have rarely been studied when the ear is exposed to a blast wave. In this study we aim to develop a ﬁnite element (FE) model of the entire ear, particularly the cochlea, for predicting the blast wave transmission from the ear canal to cochlea. We utilized a FE model of the ear, which includes the ear canal, middle ear, and uncoiled two-chambered cochlea, to simulate the cochlear response to blast overpressure (BOP) at the entrance of the ear canal with ANSYS Mechanical and Fluent in a ﬂuid–structure interface coupled analysis in the time domain. This model was developed based on previous middle and inner ear models, and the cochlea was remeshed to improve BOP simulation performance. The FE model was validated using experimentally measured blast pressure transduction from the ear canal to the middle ear and cochlea in human cadaveric temporal bones. Results from the FE model showed signiﬁcant displacements of the tympanic membrane, middle ear ossicles, and basilar membrane (BM). The stapes footplate displacement was observed to be as high as 60 lm, far exceeding the displacement during normal acoustic stimulation, when the 30 kPa (4.35 psi, 183 dB (SPL), Sound Pressure Level) of BOP was applied at the ear canal entrance. The large stapes movement caused pressures in the cochlea to exceed the physiological pressure level [< 10 Pa, 120 dB (SPL)] at a peak of 49.9 kPa, and the BM displacement was on the order of microns with a maximum displacement of 26.4 lm. The FE model of the entire human ear developed in this study provides a computational tool for prediction of blast wave transmission from the ear canal to cochlea and the

Address correspondence to Rong Z. Gan, School of Aerospace and Mechanical Engineering, University of Oklahoma, 865 Asp Avenue, Room 200, Norman, OK 73019, USA. Electronic mail: [email protected]

future applications for assisting the prevention, diagnosis, and treatment of blast-induced hearing loss. Keywords—Finite element model, Ear, Blast overpressure, Cochlear pressure, Basilar

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3D Finite Element Modeling of Blast Wave Transmission from the External Ear to Cochlea

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