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野外蟋蟀的声音传播和定向听觉:户外的神经生理学研究。

Sound transmission and directional hearing in field crickets: neurophysiological studies outdoors.

机构信息

Department of Zoology, University of Cambridge, Downing Street, Cambridge, CB2 3EJ, UK.

出版信息

J Comp Physiol A Neuroethol Sens Neural Behav Physiol. 2010 Sep;196(9):669-81. doi: 10.1007/s00359-010-0557-x. Epub 2010 Jul 23.

DOI:10.1007/s00359-010-0557-x
PMID:20652707
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3971155/
Abstract

Many studies provide detailed behavioural and neurophysiological information on the ability of crickets to localize a sound source under ideal acoustic conditions, but very little is known about how they perform in real habitats. We investigated directional hearing of crickets in the field using a neurophysiological approach, by recording the activity of the two prominent, bilaterally homologous AN1 neurons simultaneously in a cricket's habitat. The discharge and latency differences of the pair of neurons in response to conspecific chirps presented at different distances and directions were taken as a measure of directional information. The maximum hearing distance differed between individuals and weather conditions from 1 to 15 m (mean 9.2 m). Although the AN1 activity generally decreased with increasing distance, large fluctuations in the magnitude of responses occurred with distance, indicating that the intensity gradient over distance is often irregular. The directional information provided in the discharge differences of the two neurons also varied with distance. Again, there was no simple directional gradient on the transmission channel; rather, with decreasing distance to the source there were receiver locations providing suprathreshold responses, but no directional information. The consequences for the ability of field crickets to communicate acoustically close to the ground are discussed.

摘要

许多研究提供了详细的行为和神经生理学信息,说明蟋蟀在理想的声学条件下定位声源的能力,但对于它们在真实栖息地中的表现却知之甚少。我们通过在蟋蟀栖息地中同时记录两只突出的双侧同源 AN1 神经元的活动,使用神经生理学方法研究蟋蟀的定向听力。神经元对不同距离和方向的同种蟋蟀叫声的放电和潜伏期差异被用作定向信息的测量。对同种蟋蟀叫声的最大听觉距离因个体和天气条件而异,范围为 1 至 15 米(平均值为 9.2 米)。尽管 AN1 活动通常随距离的增加而降低,但在距离上响应幅度的大幅波动表明距离上的强度梯度通常是不规则的。两个神经元放电差异提供的定向信息也随距离而变化。同样,在传输通道上没有简单的定向梯度,而是随着与声源的距离减小,存在提供超阈值响应的接收位置,但没有定向信息。讨论了蟋蟀在靠近地面的地方进行声学交流的能力的后果。

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