François Deloche, Satyabrata Parida, Andrew Sivaprakasam, Michael G Heinz
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引用次数: 0
Abstract
Purpose: Frequency selectivity is a fundamental property of the peripheral auditory system; however, the invasiveness of auditory nerve (AN) experiments limits its study in the human ear. Compound action potentials (CAPs) associated with forward masking have been suggested as an alternative to assess cochlear frequency selectivity. Previous methods relied on an empirical comparison of AN and CAP tuning curves in animal models, arguably not taking full advantage of the information contained in forward-masked CAP waveforms.
Methods: To improve the estimation of cochlear frequency selectivity based on the CAP, we introduce a convolution model to fit forward-masked CAP waveforms. The model generates masking patterns that, when convolved with a unitary response, can predict the masking of the CAP waveform induced by Gaussian noise maskers. Model parameters, including those characterizing frequency selectivity, are fine-tuned by minimizing waveform prediction errors across numerous masking conditions, yielding robust estimates.
Results: The method was applied to click-evoked CAPs at the round window of anesthetized chinchillas using notched-noise maskers with various notch widths and attenuations. The estimated quality factor Q10 as a function of center frequency is shown to closely match the average quality factor obtained from AN fiber tuning curves, without the need for an empirical correction factor.
Conclusion: This study establishes a moderately invasive method for estimating cochlear frequency selectivity with potential applicability to other animal species or humans. Beyond the estimation of frequency selectivity, the proposed model proved to be remarkably accurate in fitting forward-masked CAP responses and could be extended to study more complex aspects of cochlear signal processing (e.g., compressive nonlinearities).
研究目的频率选择性是外周听觉系统的基本特性;然而,听觉神经(AN)实验的侵入性限制了人耳对其的研究。与前向掩蔽相关的复合动作电位(CAP)被认为是评估耳蜗频率选择性的替代方法。以前的方法依赖于动物模型中 AN 和 CAP 调谐曲线的经验比较,可以说没有充分利用前向掩蔽 CAP 波形中包含的信息:为了改进基于 CAP 的耳蜗频率选择性估算,我们引入了一个卷积模型来拟合前向掩蔽 CAP 波形。该模型生成的掩蔽模式与单元响应卷积后,可预测高斯噪声掩蔽器对 CAP 波形的掩蔽。模型参数,包括那些表征频率选择性的参数,通过在众多掩蔽条件下最大限度地减小波形预测误差来进行微调,从而获得稳健的估计值:结果:该方法应用于麻醉龙猫圆窗处的点击诱发 CAP,使用了不同缺口宽度和衰减的缺口噪声掩蔽器。结果表明,作为中心频率函数的估计品质因数 Q10 与从 AN 纤维调谐曲线中获得的平均品质因数非常吻合,无需使用经验校正因子:本研究建立了一种适度侵入性的耳蜗频率选择性估算方法,该方法可能适用于其他动物物种或人类。除了频率选择性的估算外,所提出的模型在拟合前向掩蔽 CAP 反应时也被证明是非常准确的,并可扩展到研究耳蜗信号处理更复杂的方面(如压缩非线性)。
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.