Fitzpatrick D C, Kuwada S, Batra R
Department of Anatomy, University of Connecticut Health Center, Farmington, Connecticut 06030-3405, USA.
J Neurosci. 2000 Feb 15;20(4):1605-15. doi: 10.1523/JNEUROSCI.20-04-01605.2000.
Interaural time differences (ITDs) are a major cue for localizing the azimuthal position of sounds. The dominant models for processing ITDs are based on the Jeffress model and predict neurons that fire maximally at a common ITD across their responsive frequency range. Such neurons are indeed found in the binaural pathways and are referred to as "peak-type." However, other neurons discharge minimally at a common ITD (trough-type), and others do not display a common ITD at the maxima or minima (intermediate-type). From recordings of neurons in the auditory cortex of the unanesthetized rabbit to low-frequency tones and envelopes of high-frequency sounds, we show that the different response types combine to form a continuous axis of best ITD. This axis extends to ITDs well beyond that allowed by the head width. In Jeffress-type models, sensitivity to large ITDs would require neural delay lines with large differences in path lengths between the two ears. Our results suggest instead that sensitivity to large ITDs is created with short delay lines, using neurons that display intermediate- and trough-type responses. We demonstrate that a neuron's best ITD can be predicted from (1) its characteristic delay, a rough measure of the delay line, (2) its characteristic phase, which defines the response type, and (3) its best frequency for ITD sensitivity. The intermediate- and trough-type neurons that have large best ITDs are predicted to be most active when sounds at the two ears are decorrelated and may transmit information about auditory space other than sound localization.
双耳时间差(ITD)是定位声音方位位置的主要线索。处理ITD的主要模型基于杰弗里斯模型,并预测在其响应频率范围内以共同ITD最大程度放电的神经元。这种神经元确实在双耳通路中被发现,并被称为“峰值型”。然而,其他神经元在共同ITD时最小程度放电(谷值型),还有其他神经元在最大值或最小值时不显示共同ITD(中间型)。通过对未麻醉兔子听觉皮层中神经元对低频音调以及高频声音包络的记录,我们表明不同的响应类型组合形成了最佳ITD的连续轴。该轴延伸到远超头部宽度所允许的ITD。在杰弗里斯型模型中,对大ITD的敏感性需要双耳之间路径长度差异很大的神经延迟线。相反,我们的结果表明,对大ITD的敏感性是通过短延迟线利用显示中间型和谷值型响应的神经元产生的。我们证明,神经元的最佳ITD可以从以下方面预测:(1)其特征延迟,这是对延迟线的粗略测量;(2)其特征相位,它定义了响应类型;(3)其对ITD敏感性的最佳频率。预计具有大最佳ITD的中间型和谷值型神经元在双耳声音去相关时最活跃,并且可能传递除声音定位之外的有关听觉空间的信息。