Corti fluid is a medium for outer hair cell force transmission.

IF 4.4 2区 医学 Q1 NEUROSCIENCES Journal of Neuroscience Pub Date : 2024-11-04 DOI:10.1523/JNEUROSCI.1033-24.2024
Mohammad Shokrian, Wei-Ching Lin, Anes Macić, Jong-Hoon Nam
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Abstract

The mammalian cochlea amplifies sounds selectively to improve frequency resolution. However, vibrations around the outer hair cells (OHCs) are amplified non-selectively. The mechanism of the selective or non-selective amplification is unknown. This study demonstrates that active force transmission through the extracellular fluid in the organ of Corti (Corti fluid) can explain how the cochlea achieves selective sound amplification despite the non-frequency-selective action of OHCs. Computational model simulations and experiments with excised cochleae from young gerbils of both sexes were exploited. OHC motility resulted in characteristic off-axis motion of the joint between the OHC and Deiters cell (ODJ). Incorporating the Corti fluid dynamics was critical to account for the ODJ motion due to OHC motility. The incorporation of pressure transmission through the Corti fluid resulted in three distinct frequency tuning patterns depending on sites in the organ of Corti. In the basilar membrane, the responses were amplified near the best-responding frequency (BF). In the ODJ region, the responses were amplified non-selectively. In the reticular lamina, the responses were amplified near the BF but suppressed in lower frequencies. The suppressive effect of OHCs was further examined by observing the changes in tuning curves due to local inhibition of OHC motility. The frequency response of the reticular lamina resembled neural tuning, such as the hypersensitivity of tuning-curve tails after hair cell damage. Our results demonstrate how active OHCs exploit the elastic frame and viscous fluid in the organ of Corti to amplify and suppress cochlear vibrations for better frequency selectivity.Significance Statement Active outer hair cells have been considered to selectively amplify the basilar membrane vibrations near the sound's tonotopic location. However, recent observations from different labs showed that outer hair cells' action is non-selective-it spreads over the broad span of traveling waves. These observations challenge the existing theory pegged to basilar-membrane mechanics. The motion at the joint between the outer hair cell and the Deiters (ODJ) cell holds the key to account for the non-selective action of outer hair cells. We show that the characteristic motions at the ODJ are explained coherently when Corti fluid acts as the medium for outer hair cell force transmission. Our results demonstrate how non-selective outer hair cell action produces selective neural responses.

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Corti 液是外毛细胞传力的介质。
哺乳动物的耳蜗会选择性地放大声音,以提高频率分辨率。然而,外毛细胞(OHC)周围的振动会被非选择性放大。选择性或非选择性放大的机制尚不清楚。本研究证明,通过柯蒂器官细胞外液(柯蒂液)的主动力传递可以解释耳蜗是如何在外毛细胞非频率选择性作用的情况下实现选择性声音放大的。我们利用计算模型模拟和从幼年沙鼠(雌雄均有)身上切除的耳蜗进行了实验。OHC的运动导致OHC和Deiters细胞(ODJ)之间的关节产生特征性离轴运动。结合 Corti 流体动力学是解释 OHC 运动导致 ODJ 运动的关键。通过 Corti 流体进行压力传递会产生三种不同的频率调谐模式,具体取决于 Corti 器官中的不同部位。在基底膜,反应在最佳反应频率(BF)附近被放大。在 ODJ 区域,反应呈非选择性放大。在网状薄层,反应在最佳响应频率附近被放大,但在较低频率时受到抑制。通过观察局部抑制 OHC 运动导致的调谐曲线变化,进一步检验了 OHC 的抑制作用。网状薄层的频率响应类似于神经调谐,如毛细胞损伤后调谐曲线尾部的超敏反应。我们的研究结果表明,活跃的外毛细胞如何利用科蒂器官中的弹性框架和粘性液体来放大和抑制耳蜗振动,从而获得更好的频率选择性。 意义声明 活跃的外毛细胞一直被认为会选择性地放大声音声调位置附近的基底膜振动。然而,最近来自不同实验室的观察结果表明,外毛细胞的作用是非选择性的--它在广泛的行波范围内扩散。这些观察结果对基底膜力学的现有理论提出了挑战。外毛细胞和 Deiters(ODJ)细胞之间的连接处的运动是解释外毛细胞非选择性作用的关键。我们的研究表明,当 Corti 流体作为外毛细胞力传递的介质时,ODJ 处的特征运动可以得到连贯的解释。我们的研究结果证明了外毛细胞的非选择性作用是如何产生选择性神经反应的。
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来源期刊
Journal of Neuroscience
Journal of Neuroscience 医学-神经科学
CiteScore
9.30
自引率
3.80%
发文量
1164
审稿时长
12 months
期刊介绍: JNeurosci (ISSN 0270-6474) is an official journal of the Society for Neuroscience. It is published weekly by the Society, fifty weeks a year, one volume a year. JNeurosci publishes papers on a broad range of topics of general interest to those working on the nervous system. Authors now have an Open Choice option for their published articles
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