Information About Spatial View in an Ensemble of Primate Hippocampal Cells

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Information About Spatial View in an Ensemble of Primate Hippocampal Cells

Edmund T. Rolls, Alessandro Treves, Robert G. Robertson, Pierre Georges-François, and Stefano Panzeri

Department of Experimental Psychology, University of Oxford, Oxford OX1 3UD, United Kingdom

Rolls, Edmund T., Alessandro Treves, Robert G. Robertson, Pierre Georges-François, and Stefano Panzeri. Informationabout spatial view in an ensemble of primate hippocampal cells.J. Neurophysiol. 79: 1797-1813, 1998. Hippocampal function wasanalyzed by making recordings from hippocampal neurons in monkeysactively walking in the laboratory. "Spatial view" cells, whichrespond when the monkey looks at a part of the environment, wereanalyzed. To assess quantitatively the information about the spatialenvironment represented by these cells, we applied informationtheoretic techniques to their responses. The average informationprovided by these cells about which location the monkey was lookingat was 0.32 bits, and the mean across cells of the maximum informationconveyed about which location was being looked at was 1.19 bits,measured in a period of 0.5 s. There were 16 locations for thisanalysis, each being one-quarter of one of the walls of the room.It also was shown that the mean spontaneous rate of firing ofthe neurons was 0.1 spikes/s, that the mean firing rate in thecenter of the spatial field of the neurons was 13.2 spikes/s,and that the mean sparseness of the representation measured ina 25-ms period was 0.04 and in a 500-ms time period was 0.19.(The sparseness is approximately equivalent to the proportionof the 25- or 500-ms periods in which the neurons showed one ormore spikes.) Next it was shown that the mean size of the viewfields of the neurons was 0.9 of a wall. In an approach to theissue of how an ensemble of neurons might together provide moreprecise information about spatial location than a single neuron,it was shown that in general the neurons had different centersfor their view fields. It then was shown that the informationfrom an ensemble of these cells about where in space is beinglooked at increases approximately linearly with the number ofcells in the ensemble. This indicates that the number of placesthat can be represented increases approximately exponentiallywith the number of cells in the population. It is concluded thatthere is an accurate representation of space "out there" in theprimate hippocampus. This representation of space out there wouldbe an appropriate part of a primate memory system involved inmemories of where in an environment an object was seen, and moregenerally in the memory of particular events or episodes, forwhich a spatial component normally provides part of the context.

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				A. Renart, N. Parga, and E. T. Rolls Backward Projections in the Cerebral Cortex: Implications for Memory Storage Neural Comput., August 15, 1999; 11(6): 1349 - 1388. [Abstract] [Full Text]

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