Modelling Motions within the Organ of Corti
Modelling Motions within the Organ of Corti
Most cochlear models used to describe the basilar membrane vibration along the cochlea are concerned with macromechanics, and often assume that the organ of Corti moves as a single unit, ignoring the individual motion of different components. New experimental technologies provide the opportunity to measure the dynamic behaviour of different components within the organ of Corti, but only for certain types of excitation. It is thus still difficult to directly measure every aspect of cochlear dynamics, particularly for acoustic excitation of the fully active cochlea. The present work studies the dynamic response of a model of the cross-section of the cochlea, at the microscopic level, using the finite element method. The elastic components are modelled with plate elements and the perilymph and endolymph are modelled with inviscid fluid elements. The individual motion of each component within the organ of Corti is calculated with dynamic pressure loading on the basilar membrane and the motions of the experimentally accessible parts are compared with measurements. The reticular lamina moves as a stiff plate, without much bending, and is pivoting around a point close to the region of the inner hair cells, as observed experimentally. The basilar membrane shows a slightly asymmetric mode shape, with maximum displacement occurring between the second-row and the third-row of the outer hair cells. The dynamics responses is also calculated, and compared with experiments, when driven by the outer hair cells. The receptance of the basilar membrane motion and of the deflection of the hair bundles of the outer hair cells is thus obtained, when driven either acoustically or electrically. In this way, the fully active linear response of the basilar membrane to acoustic excitation can be predicted by using a linear superposition of the calculated receptances and a defined gain function for the outer hair cell feedback.
Ni, Guangjian
f6ddc112-7d81-403a-b97a-7ecbc8fd4e59
Elliott, Stephen J.
721dc55c-8c3e-4895-b9c4-82f62abd3567
Baumgart, Johannes
2b226a54-8ae3-454d-8d7e-9bb6c0403cf3
Ni, Guangjian
f6ddc112-7d81-403a-b97a-7ecbc8fd4e59
Elliott, Stephen J.
721dc55c-8c3e-4895-b9c4-82f62abd3567
Baumgart, Johannes
2b226a54-8ae3-454d-8d7e-9bb6c0403cf3
Ni, Guangjian, Elliott, Stephen J. and Baumgart, Johannes
(2014)
Modelling Motions within the Organ of Corti.
12th Mechanics of Hearing, Cape Sounio, Greece.
22 - 27 Jun 2014.
5 pp
.
Record type:
Conference or Workshop Item
(Other)
Abstract
Most cochlear models used to describe the basilar membrane vibration along the cochlea are concerned with macromechanics, and often assume that the organ of Corti moves as a single unit, ignoring the individual motion of different components. New experimental technologies provide the opportunity to measure the dynamic behaviour of different components within the organ of Corti, but only for certain types of excitation. It is thus still difficult to directly measure every aspect of cochlear dynamics, particularly for acoustic excitation of the fully active cochlea. The present work studies the dynamic response of a model of the cross-section of the cochlea, at the microscopic level, using the finite element method. The elastic components are modelled with plate elements and the perilymph and endolymph are modelled with inviscid fluid elements. The individual motion of each component within the organ of Corti is calculated with dynamic pressure loading on the basilar membrane and the motions of the experimentally accessible parts are compared with measurements. The reticular lamina moves as a stiff plate, without much bending, and is pivoting around a point close to the region of the inner hair cells, as observed experimentally. The basilar membrane shows a slightly asymmetric mode shape, with maximum displacement occurring between the second-row and the third-row of the outer hair cells. The dynamics responses is also calculated, and compared with experiments, when driven by the outer hair cells. The receptance of the basilar membrane motion and of the deflection of the hair bundles of the outer hair cells is thus obtained, when driven either acoustically or electrically. In this way, the fully active linear response of the basilar membrane to acoustic excitation can be predicted by using a linear superposition of the calculated receptances and a defined gain function for the outer hair cell feedback.
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e-pub ahead of print date: 2014
Venue - Dates:
12th Mechanics of Hearing, Cape Sounio, Greece, 2014-06-22 - 2014-06-27
Organisations:
Signal Processing & Control Grp
Identifiers
Local EPrints ID: 372070
URI: http://eprints.soton.ac.uk/id/eprint/372070
PURE UUID: 039b1d88-591e-4eea-b337-14812bc932af
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Date deposited: 26 Nov 2014 17:00
Last modified: 12 Dec 2021 03:57
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Contributors
Author:
Guangjian Ni
Author:
Johannes Baumgart
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