Temporal contrast sensitivities in the range 0.33-42 Hz for optimum spatial frequency grating stimuli were measured for large populations of XG and YG neurones. For fewer cells, complete spatial contrast sensitivity profiles were measured at a series of temporal frequencies and, in some cases, at a range of levels of retinal illumination too. Contrast sensitivities were measured from responses of cells reliably different from their maintained discharges. The cells' discharges were recorded extracellularly from the binocular segment of the A laminae of the cat's dorsal lateral geniculate nucleus. At their respective optimum spatial frequencies, YG cell were more sensitive on average than XG cells for most temporal frequencies, though the average temporal contrast sensitivity profiles of both cell classes had similar shapes. The optimum temporal frequency for both cell types was around 5 Hz. XG and YG cells seem to be relatively less sensitive to low temporal frequencies than their ganglion cell counterparts. At a retinal illumination of 230 cd/m2 (pupil, 3 mm2), increasing temporal frequency in the range 0.65-21 Hz produced a relative improvement in low spatial frequency contrast sensitivity in most XG and all YG cells studied. There were some XG cells, though, which showed little or no effect of temporal frequency on their spatial contrast sensitivity curves. At all temporal frequencies, the shapes of spatial contrast sensitivity curves and the cells' temporal contrast sensitivity profiles were not markedly dependent on the criterion level set to measure 'threshold' contrast. Reducing the level of retinal illumination in the range 230-0.007 cd/m2 (pupil, 3 mm2) produced a fall in contrast sensitivities for both XG and YG cells. The loss in sensitivity was more marked at high spatial and high temporal frequencies. The similar shapes of the temporal contrast sensitivity curves of XG and YG cells weakens the suggestion that the human counterparts of these cells would provide a suitable physiological substrate for the psychophysical sustained and transient channels. Although the behaviour of XG and YG cells parallels quite closely changes in cat and human psychophysical spatial contrast sensitivities with temporal frequency and retinal illumination, many problems remain for equating results from the two fields.
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机译:对于大量XG和YG神经元,测量了在0.33-42 Hz范围内的最佳空间频率光栅刺激的时间对比敏感度。对于较少的细胞,可以在一系列时间频率上测量完整的空间对比灵敏度曲线,在某些情况下,还可以在一定范围的视网膜照明水平下测量。从可靠地不同于其维持的放电的细胞的响应中测量对比度敏感性。从猫的背外侧膝状核的薄片的双眼节的细胞外记录细胞的放电。在它们各自的最佳空间频率下,尽管两种细胞类型的平均时间对比敏感度曲线具有相似的形状,但对于大多数时间频率而言,YG细胞平均比XG细胞更敏感。两种电池类型的最佳时间频率约为5 Hz。与神经节细胞相比,XG和YG细胞似乎对低时间频率的敏感性相对较低。在230 cd / m2(瞳孔,3 mm2)的视网膜照度下,在大多数研究的XG和所有YG电池中,增加的时间频率在0.65-21 Hz范围内,相对较低的空间频率对比度敏感度有了相对改善。但是,有一些XG电池对它们的空间对比敏感度曲线几乎没有或没有时间频率的影响。在所有时间频率上,空间对比敏感度曲线的形状和细胞的时间对比敏感度分布图都不显着依赖于用于测量“阈值”对比的标准水平。将视网膜照明水平降低至230-0.007 cd / m2(瞳孔,3 mm2)范围内,会使XG和YG电池的对比度灵敏度下降。在高空间和高时间频率下,灵敏度的下降更为明显。 XG和YG细胞的时间对比敏感度曲线的相似形状削弱了以下暗示:这些细胞的人类对应物将为心理生理持续和短暂通道提供合适的生理底物。尽管XG和YG细胞的行为与猫和人类的心理物理空间对比敏感度的变化与时间频率和视网膜照明非常接近地平行变化,但仍然存在使这两个领域的结果相等的许多问题。
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