Bandpass Shape of Distortion-Product Otoacoustic Emission Ratio Functions Reflects Cochlear Frequency Tuning in Normal-Hearing Mice.

IF 2.4 3区医学 Q3 NEUROSCIENCES

Jaro-Journal of the Association for Research in Otolaryngology Pub Date : 2023-06-01 DOI:10.1007/s10162-023-00892-4

James B Dewey, Christopher A Shera

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引用次数: 3

Abstract

The frequency selectivity of the mammalian auditory system is critical for discriminating complex sounds like speech. This selectivity derives from the sharp tuning of the cochlea's mechanical response to sound, which is largely attributed to the amplification of cochlear vibrations by outer hair cells (OHCs). Due to its nonlinearity, the amplification process also leads to the generation of distortion products (DPs), some of which propagate out to the ear canal as DP otoacoustic emissions (DPOAEs). However, the insight that these signals provide about the tuned micro- and macro-mechanics underlying their generation remains unclear. Using optical coherence tomography to measure cochlear vibrations in mice, we show that the cochlea's frequency tuning is reflected in the bandpass shape that is observed in DPOAE amplitudes when the ratio of the two evoking stimulus frequencies is varied (here termed DPOAE "ratio functions"). The tuning sharpness of DPOAE ratio functions and cochlear vibrations co-varied with stimulus level, with a similar quantitative agreement in tuning sharpness observed for both apical and mid-cochlear locations. Measurement of intracochlear DPs revealed that the tuning of the DPOAE ratio functions was not caused by mechanisms that shape DPs locally near where they are generated. Instead, simple model simulations indicate that the bandpass shape is due to a more global wave interference phenomenon. It appears that the filtering of DPOAEs by wave interactions over an extended spatial region allows them to provide a window onto the frequency tuning of single cochlear locations.

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畸变积耳声发射比函数的带通形状反映正常听力小鼠耳蜗频率调谐。

哺乳动物听觉系统的频率选择性对于辨别像说话这样的复杂声音至关重要。这种选择性源于耳蜗对声音的机械反应的尖锐调谐，这在很大程度上归因于耳蜗外毛细胞(ohc)对耳蜗振动的放大。由于其非线性，放大过程也会产生失真产物(DP)，其中一些失真产物以DP耳声发射(dpoae)的形式传播到耳道。然而，这些信号提供的关于其产生背后的调谐微观和宏观力学的见解仍然不清楚。利用光学相干断层扫描测量小鼠耳蜗振动，我们发现，当两个刺激频率的比值变化时，耳蜗的频率调谐反映在DPOAE振幅中观察到的带通形状(这里称为DPOAE“比值函数”)。DPOAE比值函数和耳蜗振动的调谐锐度随刺激水平的变化而变化，耳蜗顶端和中耳蜗位置的调谐锐度具有相似的定量一致性。耳蜗内DPs的测量显示，DPOAE比率函数的调整不是由形成DPs的机制引起的，这些机制在它们产生的地方附近形成DPs。相反，简单的模型模拟表明，带通形状是由于更全局的波干涉现象。在一个扩展的空间区域内，波相互作用对dpoae的过滤似乎允许它们为单个耳蜗位置的频率调谐提供一个窗口。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Jaro-Journal of the Association for Research in Otolaryngology 医学-耳鼻喉科学

CiteScore

4.10

自引率

12.50%

发文量

审稿时长

6-12 weeks

期刊介绍： JARO is a peer-reviewed journal that publishes research findings from disciplines related to otolaryngology and communications sciences, including hearing, balance, speech and voice. JARO welcomes submissions describing experimental research that investigates the mechanisms underlying problems of basic and/or clinical significance. Authors are encouraged to familiarize themselves with the kinds of papers carried by JARO by looking at past issues. Clinical case studies and pharmaceutical screens are not likely to be considered unless they reveal underlying mechanisms. Methods papers are not encouraged unless they include significant new findings as well. Reviews will be published at the discretion of the editorial board; consult the editor-in-chief before submitting.