Minimal basilar membrane motion in low-frequency hearing

Rebecca L. Warren; Sripriya Ramamoorthy; Nikola Ciganovic; Yuan Zhang; Teresa M. Wilson; Tracy Petrie; Ruikang K. Wang; Steven L. Jacques; Tobias Reichenbach; Alfred L. Nuttall; Anders Fridberger

doi:10.1073/pnas.1606317113

Minimal basilar membrane motion in low-frequency hearing

Rebecca L. Warren, Sripriya Ramamoorthy, Nikola Ciganovic, Yuan Zhang, Teresa M. Wilson, Tracy Petrie, Ruikang K. Wang, Steven L. Jacques, Tobias Reichenbach, Alfred L. Nuttall, Anders Fridberger

Research output: Contribution to journal › Article › peer-review

43 Scopus citations

Abstract

Low-frequency hearing is critically important for speech and music perception, but no mechanical measurements have previously been available from inner ears with intact low-frequency parts. These regions of the cochlea may function in ways different from the extensively studied high-frequency regions, where the sensory outer hair cells produce force that greatly increases the soundevoked vibrations of the basilar membrane. We used laser interferometry in vitro and optical coherence tomography in vivo to study the low-frequency part of the Guinea pig cochlea, and found that sound stimulation caused motion of a minimal portion of the basilar membrane. Outside the region of peak movement, an exponential decline in motion amplitude occurred across the basilar membrane. The moving region had different dependence on stimulus frequency than the vibrations measured near the mechanosensitive stereocilia. This behavior differs substantially from the behavior found in the extensively studied high-frequency regions of the cochlea.

Original language	English (US)
Pages (from-to)	E4304-E4310
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	113
Issue number	30
DOIs	https://doi.org/10.1073/pnas.1606317113
State	Published - Jul 26 2016

Keywords

Basilar membrane
Hair cells
Hearing
Optical coherence tomography

ASJC Scopus subject areas

General

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10.1073/pnas.1606317113

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Warren, R. L., Ramamoorthy, S., Ciganovic, N., Zhang, Y., Wilson, T. M., Petrie, T., Wang, R. K., Jacques, S. L., Reichenbach, T., Nuttall, A. L., & Fridberger, A. (2016). Minimal basilar membrane motion in low-frequency hearing. Proceedings of the National Academy of Sciences of the United States of America, 113(30), E4304-E4310. https://doi.org/10.1073/pnas.1606317113

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abstract = "Low-frequency hearing is critically important for speech and music perception, but no mechanical measurements have previously been available from inner ears with intact low-frequency parts. These regions of the cochlea may function in ways different from the extensively studied high-frequency regions, where the sensory outer hair cells produce force that greatly increases the soundevoked vibrations of the basilar membrane. We used laser interferometry in vitro and optical coherence tomography in vivo to study the low-frequency part of the Guinea pig cochlea, and found that sound stimulation caused motion of a minimal portion of the basilar membrane. Outside the region of peak movement, an exponential decline in motion amplitude occurred across the basilar membrane. The moving region had different dependence on stimulus frequency than the vibrations measured near the mechanosensitive stereocilia. This behavior differs substantially from the behavior found in the extensively studied high-frequency regions of the cochlea.",

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note = "Funding Information: We thank Gemaine Stark and Sarah Foster for the harvest and vibratome sectioning of Guinea pig cochleae. This study was supported by Swedish Research Council Grant K2014-63X-14061-14-5 (to A.F.); the Torsten S{\"o}derberg Foundation (A.F.); the Stiftelsen Tysta Skolan (A.F.); the Strategic Research Area for Systems Neuroscience (A.F.); and NIH National Institute on Deafness and other Communication Disorders Grants DC00141 and 000105 (to A.L.N.), Grant DC005983 (to Peter Barr- Gillespie), Grant NS061800 (to Sue Aicher), and Grant R01DC010399 (to A.L.N, R.K.W, and S.L.J.).",

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AU - Wang, Ruikang K.

AU - Jacques, Steven L.

AU - Reichenbach, Tobias

AU - Nuttall, Alfred L.

AU - Fridberger, Anders

N1 - Funding Information: We thank Gemaine Stark and Sarah Foster for the harvest and vibratome sectioning of Guinea pig cochleae. This study was supported by Swedish Research Council Grant K2014-63X-14061-14-5 (to A.F.); the Torsten Söderberg Foundation (A.F.); the Stiftelsen Tysta Skolan (A.F.); the Strategic Research Area for Systems Neuroscience (A.F.); and NIH National Institute on Deafness and other Communication Disorders Grants DC00141 and 000105 (to A.L.N.), Grant DC005983 (to Peter Barr- Gillespie), Grant NS061800 (to Sue Aicher), and Grant R01DC010399 (to A.L.N, R.K.W, and S.L.J.).

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N2 - Low-frequency hearing is critically important for speech and music perception, but no mechanical measurements have previously been available from inner ears with intact low-frequency parts. These regions of the cochlea may function in ways different from the extensively studied high-frequency regions, where the sensory outer hair cells produce force that greatly increases the soundevoked vibrations of the basilar membrane. We used laser interferometry in vitro and optical coherence tomography in vivo to study the low-frequency part of the Guinea pig cochlea, and found that sound stimulation caused motion of a minimal portion of the basilar membrane. Outside the region of peak movement, an exponential decline in motion amplitude occurred across the basilar membrane. The moving region had different dependence on stimulus frequency than the vibrations measured near the mechanosensitive stereocilia. This behavior differs substantially from the behavior found in the extensively studied high-frequency regions of the cochlea.

AB - Low-frequency hearing is critically important for speech and music perception, but no mechanical measurements have previously been available from inner ears with intact low-frequency parts. These regions of the cochlea may function in ways different from the extensively studied high-frequency regions, where the sensory outer hair cells produce force that greatly increases the soundevoked vibrations of the basilar membrane. We used laser interferometry in vitro and optical coherence tomography in vivo to study the low-frequency part of the Guinea pig cochlea, and found that sound stimulation caused motion of a minimal portion of the basilar membrane. Outside the region of peak movement, an exponential decline in motion amplitude occurred across the basilar membrane. The moving region had different dependence on stimulus frequency than the vibrations measured near the mechanosensitive stereocilia. This behavior differs substantially from the behavior found in the extensively studied high-frequency regions of the cochlea.

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Minimal basilar membrane motion in low-frequency hearing

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