19229307

Source:http://linkedlifedata.com/resource/pubmed/id/19229307

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Predicate	Object
rdf:type	pubmed:Citation
lifeskim:mentions	umls-concept:C0007634, umls-concept:C0026336, umls-concept:C0026339, umls-concept:C0443131, umls-concept:C0549178, umls-concept:C1158478, umls-concept:C1705422, umls-concept:C1705483, umls-concept:C1882071, umls-concept:C2348395, umls-concept:C2825313
pubmed:issue	2
pubmed:dateCreated	2009-2-20
pubmed:abstractText	Grid cells in the rat entorhinal cortex display strikingly regular firing responses to the animal's position in 2-D space and have been hypothesized to form the neural substrate for dead-reckoning. However, errors accumulate rapidly when velocity inputs are integrated in existing models of grid cell activity. To produce grid-cell-like responses, these models would require frequent resets triggered by external sensory cues. Such inadequacies, shared by various models, cast doubt on the dead-reckoning potential of the grid cell system. Here we focus on the question of accurate path integration, specifically in continuous attractor models of grid cell activity. We show, in contrast to previous models, that continuous attractor models can generate regular triangular grid responses, based on inputs that encode only the rat's velocity and heading direction. We consider the role of the network boundary in the integration performance of the network and show that both periodic and aperiodic networks are capable of accurate path integration, despite important differences in their attractor manifolds. We quantify the rate at which errors in the velocity integration accumulate as a function of network size and intrinsic noise within the network. With a plausible range of parameters and the inclusion of spike variability, our model networks can accurately integrate velocity inputs over a maximum of approximately 10-100 meters and approximately 1-10 minutes. These findings form a proof-of-concept that continuous attractor dynamics may underlie velocity integration in the dorsolateral medial entorhinal cortex. The simulations also generate pertinent upper bounds on the accuracy of integration that may be achieved by continuous attractor dynamics in the grid cell network. We suggest experiments to test the continuous attractor model and differentiate it from models in which single cells establish their responses independently of each other.
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pubmed:language	eng
pubmed:journal	http://linkedlifedata.com/resource/pubmed/journal/101238922
pubmed:citationSubset	IM
pubmed:status	MEDLINE
pubmed:month	Feb
pubmed:issn	1553-7358
pubmed:author	pubmed-author:BurakYoramY, pubmed-author:FieteIla RIR
pubmed:issnType	Electronic
pubmed:volume	5
pubmed:owner	NLM
pubmed:authorsComplete	Y
pubmed:pagination	e1000291
pubmed:dateRevised	2009-11-18
pubmed:meshHeading	pubmed-meshheading:19229307-Action Potentials, pubmed-meshheading:19229307-Animals, pubmed-meshheading:19229307-Entorhinal Cortex, pubmed-meshheading:19229307-Models, Neurological, pubmed-meshheading:19229307-Motion Perception, pubmed-meshheading:19229307-Nerve Net, pubmed-meshheading:19229307-Neural Networks (Computer), pubmed-meshheading:19229307-Neural Pathways, pubmed-meshheading:19229307-Nonlinear Dynamics, pubmed-meshheading:19229307-Rats, pubmed-meshheading:19229307-Space Perception, pubmed-meshheading:19229307-Systems Integration, pubmed-meshheading:19229307-Time Factors
pubmed:year	2009
pubmed:articleTitle	Accurate path integration in continuous attractor network models of grid cells.
pubmed:affiliation	Center for Brain Science, Harvard University, Cambridge, Massachusetts, United States of America. yburak@fas.harvard.edu
pubmed:publicationType	Journal Article, Research Support, U.S. Gov't, Non-P.H.S., Research Support, Non-U.S. Gov't