Formal and Attribute-Specific Information in Primary Visual Cortex

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Formal and Attribute-Specific Information in Primary Visual Cortex

Daniel S. Reich,¹^,² Ferenc Mechler,² and Jonathan D. Victor²

¹Laboratory of Biophysics, The Rockefeller University; and ²Department of Neurology and Neuroscience, Weill Medical College of Cornell University, New York, New York 10021

Reich, Daniel S., Ferenc Mechler, and Jonathan D. Victor. Formal and Attribute-Specific Information in Primary Visual Cortex. J. Neurophysiol. 85: 305-318, 2001. We estimate the rates at which neurons in the primary visual cortex (V1) of anesthetized macaque monkeys transmit stimulus-relatedinformation in response to three types of visual stimulus. Thestimuli $---$ randomly modulated checkerboard patterns, stationary sinusoidalgratings, and drifting sinusoidal gratings $---$ have very differentspatiotemporal structures. We obtain the overall rate of informationtransmission, which we call formal information, by a direct method.We find the highest information rates in the responses of simplecells to drifting gratings (median: 10.3 bits/s, 0.92 bits/spike);responses to randomly modulated stimuli and stationary gratingstransmit information at significantly lower rates. In general,simple cells transmit information at higher rates, and over alarger range, than do complex cells. Thus in the responses ofV1 neurons, stimuli that are rapidly modulated do not necessarilyevoke higher information rates, as might be the case with motion-sensitiveneurons in area MT. By an extension of the direct method, we parsethe formal information into attribute-specific components, whichprovide estimates of the information transmitted about contrastand spatiotemporal pattern. We find that contrast-specific informationrates vary across neurons $---$ about 0.3 to 2.1 bits/s or 0.05 to 0.22bits/spike $---$ but depend little on stimulus type. Spatiotemporalpattern-specific information rates, however, depend strongly onthe type of stimulus and neuron (simple or complex). The remaininginformation rate, typically between 10 and 32% of the formal informationrate for each neuron, cannot be unambiguously assigned to eithercontrast or spatiotemporal pattern. This indicates that some informationconcerning these two stimulus attributes is confounded in theresponses of single neurons in V1. A model that considers a simplecell to consist of a linear spatiotemporal filter followed bya static rectifier predicts higher information rates than arefound in real neurons and completely fails to replicate the performanceof real cells in generating the confoundedinformation.

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