The analysis of image motion by the rabbit retina

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The analysis of image motion by the rabbit retina

C. W. Oyster

1. Micro-electrode recordings were made from rabbit retinalganglion cells or their axons. Of particular interest were direction-selectiveunits; the common on—off type represented 20·6%of the total sample (762 units), and the on-type comprised 5%of the total.

2. From the large sample of direction-selective units, it wasfound that on—off units were maximally sensitive to onlyfour directions of movement; these directions, in the visualfield, were, roughly, anterior, superior, posterior and inferior.The on-type units were maximally sensitive to only three directions:anterior, superior and inferior.

3. The direction-selective unit's responses vary with stimulusvelocity; both unit types are more sensitive to velocity changethan to absolute speed. On—off units respond to movementat speeds from 6'/sec to 10°/sec; the on-type units respondedas slowly as 30''/sec up to about 2°/sec. On-type unitsare clearly slow-movement detectors.

4. The distribution of direction-selective units depends onthe retinal locality. On—off units are more common outsidethe `visual streak' (area centralis) than within it, while thereverse is true for the on-type units.

5. A stimulus configuration was found which would elicit responsesfrom on-type units when the stimulus was moved in the null direction.This `paradoxical response' was shown to be associated withthe silent receptive field surround.

6. The four preferred directions of the on—off units wereshown to correspond to the directions of retinal image motionproduced by contractions of the four rectus eye muscles. Thisfact, combined with data on velocity sensitivity and retinaldistribution of on—off units, suggests that the on—offunits are involved in control of reflex eye movements.

7. The on—off direction-selective units may provide errorsignals to a visual servo system which minimizes retinal imagemotion. This hypothesis agrees with the known characteristicsof the rabbit's visual following reflexes, specifically, theslow phase of optokinetic nystagmus.

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