Wagner H
California Institute of Technology, Division of Biology, Pasadena 91125.
J Comp Physiol A. 1992 Jan;170(1):3-11. doi: 10.1007/BF00190396.
This paper investigates the ability of neurons in the barn owl's (Tyto alba) inferior colliculus to sense brief appearances of interaural time difference (ITD), the main cue for azimuthal sound localization in this species. In the experiments, ITD-tuning was measured during presentation of a mask-probe-mask sequence. The probe consisted of a noise having a constant ITD, while the mask consisted of binaurally uncorrelated noise. Collicular neurons discriminated between the probe and masking noise by showing rapid changes from untuned to tuned and back to untuned responses. The curve describing the relation between probe duration and the degree of ITD-tuning resembled a leaky-integration process with a time constant of about 2 ms. Many neurons were ITD-tuned when probe duration was below 1 ms. These extremely short effective probe durations are interpreted as evidence for neuronal convergence within the pathway computing ITD. The minimal probe duration necessary for ITD-tuning was independent of the bandwidth of the neurons' frequency tuning and also of the best frequency of a neuron. Many narrowly tuned neurons having different best frequencies converge to form a broad-band neuron. To yield the short effective probe durations the convergence must occur in strong temporal synchronism.
本文研究了仓鸮(Tyto alba)中脑下丘神经元感知耳间时间差(ITD)短暂出现的能力,ITD是该物种中方位声音定位的主要线索。在实验中,在呈现掩蔽-探测-掩蔽序列期间测量ITD调谐。探测音由具有恒定ITD的噪声组成,而掩蔽音由双耳不相关噪声组成。中脑下丘神经元通过显示从未调谐到调谐再回到未调谐反应的快速变化,区分探测音和掩蔽噪声。描述探测音持续时间与ITD调谐程度之间关系的曲线类似于具有约2毫秒时间常数的泄漏积分过程。当探测音持续时间低于1毫秒时,许多神经元对ITD进行了调谐。这些极短的有效探测音持续时间被解释为计算ITD的通路内神经元汇聚的证据。ITD调谐所需的最小探测音持续时间与神经元频率调谐的带宽无关,也与神经元的最佳频率无关。许多具有不同最佳频率的窄调谐神经元汇聚形成一个宽带神经元。为了产生短的有效探测音持续时间,汇聚必须在强烈的时间同步中发生。
