Auditory Cellular Cooperativity Probed Via Spontaneous Otoacoustic Emissions

Christopher Bergevin, Rebecca Whiley, Hero Wit, Geoffrey Manley, Pim van Dijk
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Abstract

As a sound pressure detector that uses energy to boost both its sensitivity and selectivity, the inner ear is an active non-equilibrium system. The collective processes of the inner ear giving rise to this exquisite functionality remain poorly understood. One manifestation of the active ear across the animal kingdom is the presence of spontaneous otoacoustic emission (SOAE), idiosyncratic arrays of spectral peaks that can be measured using a sensitive microphone in the ear canal.1 Current SOAE models attempt to explain how multiple peaks arise, and generally assume a spatially-distributed tonotopic system. However, the nature of the generators, their coupling, and the role of noise (e.g., Brownian motion) are hotly debated, especially given the inner ear morphological diversity across vertebrates. One means of probing these facets of emission generation is studying fluctuations in SOAE peak properties, which produce amplitude (AM) and frequency modulations (FM). These properties are likely related to the presence of noise affecting active cellular generation elements, and the coupling between generators. To better biophysically constrain models, this study characterizes the fluctuations in filtered SOAE peak waveforms, focusing on interrelations within and across peaks. A systematic approach is taken, examining three species that exhibit disparate inner ear morphologies: humans, barn owls, and green anole lizards. To varying degrees across all three groups, SOAE peaks have intra- (IrP) and interpeak (IPP) correlations indicative of interactions between generative elements. Activity from anole lizards, whose auditory sensory organ is relatively much smaller than that of humans or barn owls, showed a much higher incidence of IPP correlations. Taken together, we propose that these data are indicative of SOAE cellular generators acting cooperatively, allowing the ear to function as an optimized detector.
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通过自发声发射探测听觉细胞的合作性
作为一个利用能量提高灵敏度和选择性的声压探测器,内耳是一个活跃的非平衡系统。人们对内耳产生这种精妙功能的集体过程仍然知之甚少。自发耳声发射(SOAE)是动物界活跃耳朵的一种表现形式,它是一种特异的频谱峰阵列,可通过耳道中的灵敏麦克风进行测量1。1 目前的 SOAE 模型试图解释多峰值是如何产生的,一般假定调谐系统在空间上是分布的。然而,对于发生器的性质、它们之间的耦合以及噪声(如布朗运动)的作用还存在激烈的争论,特别是考虑到脊椎动物内耳形态的多样性。探测发射产生的这些方面的一种方法是研究产生振幅(AM)和频率调制(FM)的 SOAE 峰值特性的波动。这些特性可能与影响活性细胞发生元件的噪声存在以及发生器之间的耦合有关。为了更好地从生物物理角度对模型进行约束,本研究描述了滤波 SOAE 峰值波形的波动特征,重点是峰值内和峰值间的相互关系。本研究采用了一种系统的方法,对人类、谷仓猫头鹰和绿鬣蜥这三种表现出不同内耳形态的物种进行了研究。在这三类物种中,SOAE 峰值在不同程度上具有峰内(IrP)和峰间(IPP)相关性,表明生成要素之间存在相互作用。踝蜥的听觉感觉器官比人类或仓鸮的小得多,其活动显示出更高的 IPP 相关性。综上所述,我们认为这些数据表明,SOAE细胞发生器协同作用,使耳朵发挥了优化检测器的功能。
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