Resultant pressure distribution pattern along the basilar membrane in the spiral shaped cochlea

TL;DR

This study models the pressure distribution along the basilar membrane in the spiral cochlea, revealing how its geometry influences wave energy distribution and highlighting the importance of detailed cochlear structure for hearing mechanics.

Contribution

It introduces a 3D fluid model with an idealized spiral geometry, analyzing pressure patterns and mode dependence, advancing understanding of cochlear mechanics beyond previous approximations.

Findings

Pressure on the basilar membrane varies along its spanwise direction.

Maximum pressure difference location depends on spiral mode.

Higher modes show non-zero velocities, indicating complex geometry effects.

Abstract

Cochlea is an important auditory organ in the inner ear. In most mammals, it is coiled as a spiral. Whether this specific shape influences hearing is still an open problem. By employing a three dimensional fluid model of the cochlea with an idealized geometry, the influence of the spiral geometry of the cochlea is examined. We obtain solutions of the model through a conformal transformation in a long-wave approximation. Our results show that the net pressure acting on the basilar membrane is not uniform along its spanwise direction. Also, it is shown that the location of the maximum of the spanwise pressure difference in the axial direction has a mode dependence. In the simplest pattern, the present result is consistent with the previous theory based on the WKB-like approximation [D. Manoussaki, Phys. Rev. Lett. 96, 088701(2006)]. In this mode, the pressure difference in the spanwise direction is a monotonic function of the distance from the apex and the normal velocity across the channel width is zero. Thus in the lowest order approximation, we can neglect the existance of the Reissner's membrane in the upper channel. However, higher responsive modes show different behavior and, thus, the real maximum is expected to be located not exactly at the apex, but at a position determined by the spiral geometry of the cochlea and the width of the cochlear duct. In these modes, the spanwise normal velocities are not zero. Thus, it indicates that one should take into account of the detailed geometry of the cochlear duct for a more quantitative result. The present result clearly demonstrates that not only the spiral geometry, but also the geometry of the cochlear duct play decisive roles in distributing the wave energy.