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家猫的响度感知:等响度轮廓的反应时间估计及重振效应

Loudness perception in the domestic cat: reaction time estimates of equal loudness contours and recruitment effects.

作者信息

May Bradford J, Little Nicole, Saylor Stephanie

机构信息

Center for Hearing and Balance, Department of Otolaryngology-Head and Neck Surgery, Johns Hopkins University School of Medicine, Traylor Research Building, Room 521, 720 Rutland Avenue, Baltimore, MD 21205, USA.

出版信息

J Assoc Res Otolaryngol. 2009 Jun;10(2):295-308. doi: 10.1007/s10162-009-0157-z. Epub 2009 Feb 7.

Abstract

The domestic cat is the primary physiological model of loudness coding and recruitment. At present, there are no published descriptions of loudness perception in this species. This study used a reaction time task to characterize loudness perception in six behaviorally trained cats. The psychophysical approach was based on the assumption that sounds of equal loudness elicit responses of equal latency. The resulting equal latency contours reproduced well-known features of human equal loudness contours. At the completion of normal baseline measures, the cats were exposed to intense sound to investigate the behavioral correlates of loudness recruitment, the abnormally rapid growth of loudness that is commonly associated with hearing loss. Observed recruitment effects were similar in magnitude to those that have been reported in hearing-impaired humans. Linear hearing aid amplification is known to improve speech intelligibility but also exacerbate recruitment in impaired listeners. The effects of speech spectra and amplification on recruitment were explored by measuring the growth of loudness for natural and amplified vowels before and after sound exposure. Vowels produced more recruitment than tones, and the effect was exacerbated by the selective amplification of formant structure. These findings support the adequacy of the domestic cat as a model system for future investigations of the auditory processes that underlie loudness perception, recruitment, and hearing aid design.

摘要

家猫是响度编码和重振的主要生理模型。目前,尚无关于该物种响度感知的公开描述。本研究采用反应时任务来表征六只经过行为训练的猫的响度感知。心理物理学方法基于这样的假设,即等响度的声音引发等潜伏期的反应。由此产生的等潜伏期轮廓很好地再现了人类等响度轮廓的已知特征。在完成正常基线测量后,让猫暴露于高强度声音中,以研究响度重振的行为相关性,响度重振是指响度异常快速增长,通常与听力损失有关。观察到的重振效应在程度上与听力受损人类中报道的效应相似。已知线性助听器放大可提高言语可懂度,但也会加剧听力受损者的重振。通过测量声音暴露前后自然元音和放大元音的响度增长,探讨了语音频谱和放大对重振的影响。元音比音调产生更多的重振,并且共振峰结构选择性放大加剧了这种效应。这些发现支持家猫作为未来研究响度感知、重振和助听器设计背后听觉过程的模型系统的适用性。

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本文引用的文献

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