Department of Psychology and Neuroscience, Dalhousie University, 1355 Oxford Street, PO Box 15000, Halifax, NS B3H 4R2, Canada.
J Acoust Soc Am. 2012 May;131(5):4023-9. doi: 10.1121/1.3701877.
The current understanding of mammalian sound localization is that azimuthal (horizontal) position assignments are dependent upon the relative activation of two populations of broadly-tuned hemifield neurons with overlapping medial borders. Recent psychophysical work has provided evidence for a third channel of low-frequency interaural time difference (ITD)-sensitive neurons tuned to the azimuthal midline. However, the neurophysiological data on free-field azimuth receptive fields, especially of cortical neurons, has primarily studied high-frequency cells whose receptive fields are more likely to have been shaped by interaural level differences (ILDs) than ITDs. In four experiments, a selective adaptation paradigm was used to probe for the existence of a midline channel in the domain of ILDs. If no midline channel exists, symmetrical adaptation of the lateral channels should not result in a shift in the perceived intracranial location of subsequent test tones away from the adaptors because the relative activation of the two channels will remain unchanged. Instead, results indicate a shift in perceived test tone location away from the adaptors, which supports the existence of a midline channel in the domain of ILDs. Interestingly, this shift occurs not only at high frequencies, traditionally associated with ILDs in natural settings, but at low frequencies as well.
目前对于哺乳动物声音定位的理解是,方位(水平)位置的分配取决于两个具有重叠内侧边界的广泛调谐半场神经元群体的相对激活。最近的心理物理学研究为第三个通道提供了证据,即对中线上低频的耳间时间差(ITD)敏感的神经元。然而,关于自由场方位感受野的神经生理学数据,特别是皮质神经元的,主要研究了高频细胞,其感受野更有可能是由耳间水平差(ILDs)而不是 ITDs 形成的。在四个实验中,使用选择性适应范式来探测在ILD 域中是否存在中线通道。如果不存在中线通道,那么对侧通道的对称适应不应导致随后测试音的感知颅内位置远离适应器,因为两个通道的相对激活将保持不变。相反,结果表明测试音的感知位置从适应器上发生了偏移,这支持了ILD 域中存在中线通道的观点。有趣的是,这种偏移不仅发生在高频,这与自然环境中的 ILD 传统上相关,而且也发生在低频。