We recorded the activity of single neurons in the lateral geniculate nucleus, primary visual cortex (the first cortical stage of visual processing), and inferior temporal cortex (the last cortical stage), to study the mechanisms underlying visual perception. When the responses were analyzed for the information they contained, we found that the response patterns could be represented as the sum of several (3-6) simultaneous, independent patterns of activity. These activity patterns were analyzed as a temporal code, and this code was found to contain more information than that conveyed by the response strength, the usual measure of neuronal response. Conceptualizing the neuron as having several independent activity patterns allowed us to use the responses elicited by one set of visual patterns to predict those elicited by other patterns. We also found that neurons in inferior temporal cortex recorded from while monkeys perform a delayed matching-to-sample task carry stimulus-specific information differentiating the pattern stimuli, and reflecting whether a given stimulus is the sample, the match, or the nonmatch. The change in the neuronal response across conditions for a few stimuli could be used to predict the change in neuronal response to other stimuli across those same conditions. Inferior temporal neurons also carry information about the stimulus being searched for (i.e. the sample) when the stimulus is either the match or nonmatch. Using a different model we were able to show how the responses to the stimulus being viewed were modified by the responses to the preceding stimulus. Each member of a neuronal pair recorded from simultaneously with a single electrode in a given cortical visual area is independent of the other, i.e., their information adds. This suggests that local processing is carried out by adding independent analyses of the stimulus being viewed.

Agency
National Institute of Health (NIH)
Institute
National Institute of Mental Health (NIMH)
Type
Intramural Research (Z01)
Project #
1Z01MH002032-02
Application #
3845210
Study Section
Project Start
Project End
Budget Start
Budget End
Support Year
2
Fiscal Year
1992
Total Cost
Indirect Cost
Name
U.S. National Institute of Mental Health
Department
Type
DUNS #
City
State
Country
United States
Zip Code
Nakahara, Hiroyuki; Amari, Shun-ichi; Richmond, Barry J (2006) A comparison of descriptive models of a single spike train by information-geometric measure. Neural Comput 18:545-68
Shidara, Munetaka; Richmond, Barry J (2005) Effect of visual noise on pattern recognition. Exp Brain Res 163:239-41
Richmond, Barry; Wiener, Matthew (2004) Recruitment order: a powerful neural ensemble code. Nat Neurosci 7:97-8
Wiener, Matthew C; Richmond, Barry J (2003) Decoding spike trains instant by instant using order statistics and the mixture-of-Poissons model. J Neurosci 23:2394-406
Wiener, Matthew C; Richmond, Barry J (2002) Model based decoding of spike trains. Biosystems 67:295-300
Shidara, Munetaka; Richmond, Barry J (2002) Anterior cingulate: single neuronal signals related to degree of reward expectancy. Science 296:1709-11
Richmond, B (2001) Neuroscience. Information coding. Science 294:2493-4
Wiener, M C; Oram, M W; Liu, Z et al. (2001) Consistency of encoding in monkey visual cortex. J Neurosci 21:8210-21
Oram, M W; Hatsopoulos, N G; Richmond, B J et al. (2001) Excess synchrony in motor cortical neurons provides redundant direction information with that from coarse temporal measures. J Neurophysiol 86:1700-16
Liu, Z; Richmond, B J (2000) Response differences in monkey TE and perirhinal cortex: stimulus association related to reward schedules. J Neurophysiol 83:1677-92

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