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无躯体运动的耳声发射:静纤毛力学能驱动哺乳动物的耳蜗吗?

Otoacoustic emissions without somatic motility: can stereocilia mechanics drive the mammalian cochlea?

作者信息

Liberman M C, Zuo Jian, Guinan J J

机构信息

Eaton-Peabody Laboratory, Massachusetts Eye & Ear Infirmary, Boston, Massachusetts 02114, USA.

出版信息

J Acoust Soc Am. 2004 Sep;116(3):1649-55. doi: 10.1121/1.1775275.

DOI:10.1121/1.1775275
PMID:15478431
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1805783/
Abstract

Distortion product otoacoustic emissions (DPOAEs) evoked by low-level tones are a sensitive indicator of outer hair cell (OHC) function. High-level DPOAEs are less vulnerable to cochlear insult, and their dependence on the OHC function is more controversial. Here, the mechanism underlying high-level DPOAE generation is addressed using a mutant mouse line lacking prestin, the molecular motor driving OHC somatic motility, required for cochlear amplification. With prestin deletion, attenuated DPOAEs were measurable at high sound levels. DPOAE thresholds were shifted by approximately 50 dB, matching the loss of cochlear amplifier gain measured in compound action potentials. In contrast, at high sound levels, distortion products in the cochlear microphonic (CM) of mutants were not decreased re wildtypes (expressed re CM at the primaries). Distortion products in both CM and otoacoustic emissions disappeared rapidly after death. The results show that OHC somatic motility is not necessary for the production of DPOAEs at high SPLs. They also suggest that the small, physiologically vulnerable DPOAE that remains without prestin-based motility is due directly to the mechanical nonlinearity associated with stereociliary transduction, and that this stereocilia mechanical nonlinearity is robustly coupled to the motion of the cochlear partition to the extent that it can drive the middle ear.

摘要

低强度纯音诱发的畸变产物耳声发射(DPOAE)是外毛细胞(OHC)功能的敏感指标。高强度DPOAE对耳蜗损伤的敏感性较低,其对OHC功能的依赖性更具争议性。在此,我们使用一种缺乏prestin的突变小鼠品系来探讨高强度DPOAE产生的机制,prestin是驱动OHC体细胞运动的分子马达,是耳蜗放大所必需的。随着prestin的缺失,在高声强下可测量到衰减的DPOAE。DPOAE阈值偏移约50 dB,与复合动作电位中测量到的耳蜗放大器增益损失相匹配。相比之下,在高声强下,突变体耳蜗微音器电位(CM)中的畸变产物与野生型相比并未降低(相对于初级频率下的CM表示)。CM和耳声发射中的畸变产物在死后迅速消失。结果表明,OHC体细胞运动对于高声强下DPOAE的产生并非必需。它们还表明,在没有基于prestin的运动情况下仍然存在的微小、生理上易受影响的DPOAE直接归因于与静纤毛转导相关的机械非线性,并且这种静纤毛机械非线性与耳蜗隔的运动紧密耦合,以至于它可以驱动中耳。

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