Tonotopically arranged traveling waves in the miniature hearing organ of bushcrickets.

Arun Palghat Udayashankar,Manuela Nowotny,Manfred Kössl,Melissa Coleman

doi:10.1371/journal.pone.0031008

Arun Palghat Udayashankar, Manuela Nowotny + Show 2 more

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https://doi.org/10.1371/journal.pone.0031008

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Journal: PloS one	Publication Date: Feb 13, 2012
Citations: 72	License type: CC BY 4.0

Affiliation: Goethe University Frankfurt

Abstract

Place based frequency discrimination (tonotopy) is a fundamental property of the coiled mammalian cochlea. Sound vibrations mechanically conducted to the hearing organ manifest themselves into slow moving waves that travel along the length of the organ, also referred to as traveling waves. These traveling waves form the basis of the tonotopic frequency representation in the inner ear of mammals. However, so far, due to the secure housing of the inner ear, these waves only could be measured partially over small accessible regions of the inner ear in a living animal. Here, we demonstrate the existence of tonotopically ordered traveling waves covering most of the length of a miniature hearing organ in the leg of bushcrickets in vivo using laser Doppler vibrometery. The organ is only 1 mm long and its geometry allowed us to investigate almost the entire length with a wide range of stimuli (6 to 60 kHz). The tonotopic location of the traveling wave peak was exponentially related to stimulus frequency. The traveling wave propagated along the hearing organ from the distal (high frequency) to the proximal (low frequency) part of the leg, which is opposite to the propagation direction of incoming sound waves. In addition, we observed a non-linear compression of the velocity response to varying sound pressure levels. The waves are based on the delicate micromechanics of cellular structures different to those of mammals. Hence place based frequency discrimination by traveling waves is a physical phenomenon that presumably evolved in mammals and bushcrickets independently.

Highlights

Georg von Bekesy was awarded the Nobel Prize in 1961 for his discovery of traveling waves in the cochleae of human cadavers [1]
The dorsal wall of the acoustic trachea shows a systematic variation in width along the organ with the low frequency region being wider (Fig. 1b) and the gradient in scolopidial cap cell dimension provides a mass gradient along the organ
Unlike the basilar membrane in mammals that is surrounded by fluid on both sides, the crista acustica (CA) is loaded with fluid on top and air below

Summary

Introduction

Georg von Bekesy was awarded the Nobel Prize in 1961 for his discovery of traveling waves in the cochleae of human cadavers [1]. The coiled shape and tough access to the cochlea impede measurements, and a common solution is to break open the scala tympani in the basal turn and measure the basilar membrane response there [8,9,10,11]. This leads to measurements that are quite restricted in space so that only limited in-vivo data are available from other turns of the cochlea that process important behaviourally relevant frequencies in mammals

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