The dynamics of the cat retinal X cell centre.

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The dynamics of the cat retinal X cell centre.

J D Victor

Department of Neurology, Cornell University Medical College, New York City, New York 10021.

1. The dynamics of the centre mechanism of individual cat Xretinal ganglion cells is investigated. The visual stimuli consistof temporal contrast modulation of stationary patterns. In orderto study the response of the centre mechanism, patterns wereeither sine gratings of high spatial frequency or small circularspots positioned over the receptive-field centre. 2. Responsesto contrast reversal are approximately linear. However, as themodulation depth of the stimulus increases, responses becomemore transient. Ganglion cell responses show this phenomenonat moderate contrasts (e.g. 0.1), which do not elicit dischargesthat approach the maximum firing rate of the ganglion cell.3. A sequence of dynamical models are constructed from responseselicited by sum-of-sinusoids modulation of the spatial pattern.The first model is strictly linear. It consists of a seriesof low-pass filters and a single high-pass filter. The linearmodel predicts the approximate shape of the step response, butdoes not account for the change in shape of the response asa function of modulation depth. 4. The second model, a quasi-linearmodel, allows the 'linear' dynamics to vary slowly with a neuralmeasure of contrast. The main effect of high contrast is a shortertime constant in the high-pass filter. This model accounts qualitativelyfor the increased transience of the response, but fails to predictthe magnitude of the effect at higher modulation depths. 5.In the third model, the transfer characteristics of the centreresponse adjust rapidly as contrast changes. This intrinsicallynon-linear model provides excellent agreement with observedresponse to steps and more complex modulation patterns. 6. Thenon-linearity necessitated by a voltage-to-spikes transductionis analysed quantitatively. In most ganglion cells, a simpletruncation at 0 impulses/s (and no saturation) explains thechanges in apparent gain and mean firing rate that occur asmodulation depth is increased. A non-linear voltage-to-spiketransduction per se cannot account for the observed effect ofcontrast on dynamics. 7. The parameters of the dynamical modelare measured for a population of twenty-seven X ganglion cells(nineteen on-centre and eight off-centre). The low-pass stageand the strength of the high-pass stage are relatively uniformacross the population. The over-all gain and the dynamics ofthe high-pass stage vary substantially across the population,but show no consistent dependence on the on-off distinctionor on retinal location. Some implications of this variabilityfor retinal function are discussed.

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