Journal
PHILOSOPHICAL TRANSACTIONS OF THE ROYAL SOCIETY B-BIOLOGICAL SCIENCES
Volume 369, Issue 1635, Pages -Publisher
ROYAL SOC
DOI: 10.1098/rstb.2012.0511
Keywords
hippocampus; entorhinal cortex; grid cells; cortex; spatial representation; attractor network
Categories
Funding
- Kavli Foundation
- Centre of Excellence from the Research Council of Norway
- European Research Council ('CIRCUIT') [232608]
- European Commission's 7th Framework ICT Programme for Future Emerging Technologies ('GRIDMAP') [600725]
- European Research Council (ERC) [232608] Funding Source: European Research Council (ERC)
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One of the major breakthroughs in neuroscience is the emerging understanding of how signals from the external environment are extracted and represented in the primary sensory cortices of the mammalian brain. The operational principles of the rest of the cortex, however, have essentially remained in the dark. The discovery of grid cells, and their functional organization, opens the door to some of the first insights into the workings of the association cortices, at a stage of neural processing where firing properties are shaped not primarily by the nature of incoming sensory signals but rather by internal self-organizing principles. Grid cells are place-modulated neurons whose firing locations define a periodic triangular array overlaid on the entire space available to a moving animal. The unclouded firing pattern of these cells is rare within the association cortices. In this paper, we shall review recent advances in our understanding of the mechanisms of grid-cell formation which suggest that the pattern originates by competitive network interactions, and we shall relate these ideas to new insights regarding the organization of grid cells into functionally segregated modules.
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