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猕猴大细胞通路视网膜神经节细胞中的抑制性周边和对比度增益

Suppressive surrounds and contrast gain in magnocellular-pathway retinal ganglion cells of macaque.

作者信息

Solomon Samuel G, Lee Barry B, Sun Hao

机构信息

Center for Neural Science, New York University, New York, New York 10003, USA.

出版信息

J Neurosci. 2006 Aug 23;26(34):8715-26. doi: 10.1523/JNEUROSCI.0821-06.2006.

DOI:10.1523/JNEUROSCI.0821-06.2006
PMID:16928860
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2598390/
Abstract

The modulation sensitivity of visual neurons can be influenced by remote stimuli which, when presented alone, cause no change in the ongoing discharge rate of the neuron. We show here that the extraclassical surrounds that underlie these effects are present in magnocellular-pathway (MC) but not in parvocellular-pathway (PC) retinal ganglion cells of the macaque. The response of MC cells to drifting gratings and flashing spots was halved by drifting or contrast-reversing gratings surrounding their receptive fields, but PC cell responses were unaffected. The suppression cannot have arisen from the classical receptive field, or been caused by scattered light, because it could be evoked by annuli that themselves caused little or no response from the cell, and is consistent with the action of a divisive suppressive mechanism. Suppression in MC cells was broadly tuned for spatial and temporal frequency and greater at high contrast. If perceptual phenomena with similar stimulus contexts, such as the "shift effect" and saccadic suppression, have a retinal component, then they reflect the activity of the MC pathway.

摘要

视觉神经元的调制敏感性会受到远距离刺激的影响,这些刺激单独呈现时,不会使神经元的持续放电率发生变化。我们在此表明,构成这些效应基础的超经典外周存在于猕猴的大细胞通路(MC)视网膜神经节细胞中,而在小细胞通路(PC)视网膜神经节细胞中则不存在。MC细胞对漂移光栅和闪烁光斑的反应,会被其感受野周围漂移或对比度反转的光栅减半,但PC细胞的反应不受影响。这种抑制不可能源于经典感受野,也不是由散射光引起的,因为它可以由本身对细胞几乎没有或没有引起反应的环形物诱发,并且与一种分裂性抑制机制的作用一致。MC细胞中的抑制在空间和时间频率上具有广泛的调谐,并且在高对比度时更强。如果具有相似刺激背景的感知现象,如“移位效应”和扫视抑制,具有视网膜成分,那么它们反映了MC通路的活动。

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