Velocity tuning of cells in dorsal lateral geniculate nucleus and retina of the cat.

Velocity tuning curves were measured for on-center cells in the dorsal lateral geniculate nucleus of the cat using a stimulus approximately the height and one-fourth the width of the hand-plotted receptive-field center. The standard stimulus strength was 1 log unit above the mesopic background luminance. Lateral geniculate Y-cells had significantly higher preferred velocities than geniculate X-cells when cells with receptive fields having the same range of retinal eccentricities were compared. Preferred velocity increased for both classes of cells as a function of retinal eccentricity. For all geniculate cells, preferred velocity increased with stimulus strength, showing an approximately threefold increase in preferred velocity for each log unit of stimulus strength. Preferred velocity was measured for on-center retinal ganglion cells with receptive fields at the same range of retinal eccentricities as the geniculate sample and under the same stimulus conditions. Preferred velocities of retinal ganglion Y-cells were significantly higher than those of ganglion X-cells, and as for geniculate cells, preferred velocities increased with increasing stimulus strength. However, the classes were better separated in the geniculate than in the retina; with geniculate X-cells having lower preferred velocities than retinal X-cells, and the geniculate Y-cells having higher preferred velocities than retinal Y-cells. For retinal ganglion cells, smaller receptive-field center sizes of the X-cells than the Y-cells could account in large part for the lower preferred velocities of the X-cells. However, for geniculate cells, differences in receptive-field center size could not account as well for the differences in preferred velocity between X- and Y-cells. Furthermore, field size differences could not account for the differences in preferred velocity between ganglion and geniculate cells of the same functional class. Experiments comparing responses to moving stimuli and flashed stationary stimuli show that stimuli moving at high velocities are in effect equivalent to brief-duration flashes, and responses are governed by the same laws of temporal summation in both cases. When velocity tuning curves were measured with long bars that enhanced peripheral inhibition, geniculate X- and Y-cells were better separated than ganglion X- and Y-cells, not only with respect to preferred velocity but also, with respect to velocity selectivity (width of the velocity tuning curve) and differential velocity sensitivity (slope of the leg of the velocity tuning curves ascending from low velocities to the peak).(ABSTRACT TRUNCATED AT 400 WORDS)