Synchronous Period-Doubling in Flicker Vision of Salamander and Man

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J Neurophysiol 79: 1869-1878, 1998;
0022-3077/98 $5.00

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The Journal of Neurophysiology Vol. 79 No. 4 April 1998, pp. 1869-1878
Copyright ©1998 The American Physiological Society

Synchronous Period-Doubling in Flicker Vision of Salamander and Man

Daniel W. Crevier and Markus Meister

Department of Molecular and Cellular Biology, Harvard University, Cambridge, Massachusetts 02138

Crevier, Daniel W. and Markus Meister. Synchronous period-doubling in flicker vision of salamander and man. J. Neurophysiol.79: 1869-1878, 1998. Periodic flashes of light have long servedto probe the temporal properties of the visual system. Here weshow that during rapid flicker of high contrast and intensitythe eye reports to the brain only every other flash of light.In this regime, retinal ganglion cells of the salamander firespikes on alternating flashes. Neurons across the entire retinaare locked to the same flashes. The effect depends sharply oncontrast and flash frequency. It results from a period-doublingbifurcation in retinal processing, and a simple model of nonlinearfeedback reproduces the phenomenon. Pharmacological studies indicatethat the critical feedback interactions require only cone photoreceptorsand bipolar cells. Analogous period-doubling is observed in thehuman visual system. Under bright full-field flicker, the electroretinogram(ERG) shows a regime of period-doubling between 30 and 70 Hz.In visual evoked potentials from the occiput, the subharmoniccomponent is even stronger. By analyzing the accompanying perceptualeffects, we find that retinal period-doubling begins in the peripheryof the visual field, and that it is the cause of a long mysteriousillusory flicker pattern.

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