A temporal mechanism for generating the phase precession of hippocampal place cells
Document Type
Article
Publication Date
1-1-2000
Abstract
The phase relationship between the activity of hippocampal place cells and the hippocampal theta rhythm systematically precesses as the animal runs through the region in an environment called the place field of the cell. We present a minimal biophysical model of the phase precession of place cells in region CA3 of the hippocampus. The model describes the dynamics of two coupled point neurons - namely, a pyramidal cell and an interneuron, the latter of which is driven by a pacemaker input. Outside of the place field, the network displays a stable, background firing pattern that is locked to the theta rhythm. The pacemaker input drives the interneuron, which in turn activates the pyramidal cell. A single stimulus to the pyramidal cell from the dentate gyrus, simulating entrance into the place field, reorganizes the functional roles of the cells in the network for a number of cycles of the theta rhythm. In the reorganized network, the pyramidal cell drives the interneuron at a higher frequency than the theta frequency, thus causing a systematic precession relative to the theta input. The frequency of the pyramidal cell can vary to account for changes in the animal's running speed. The transient dynamics end after up to 360 degrees of phase precession when the pacemaker input to the interneuron occurs at a phase to return the network to the stable background firing pattern, thus signaling the end of the place field. Our model, in contrast to others, reports that phase precession is a temporally, and not spatially, controlled process. We also predict that like pyramidal cells, interneurons phase precess. Our model provides a mechanism for shutting off place cell firing after the animal has crossed the place field, and it explains the observed nearly 360 degrees of phase precession. We also describe how this model is consistent with a proposed autoassociative memory role of the CA3 region.
Identifier
0033926803 (Scopus)
Publication Title
Journal of Computational Neuroscience
External Full Text Location
https://doi.org/10.1023/A:1008976210366
ISSN
09295313
PubMed ID
10946990
First Page
5
Last Page
30
Issue
1
Volume
9
Grant
421540
Fund Ref
National Science Foundation
Recommended Citation
Bose, Amitabha; Booth, Victoria; and Recce, Michael, "A temporal mechanism for generating the phase precession of hippocampal place cells" (2000). Faculty Publications. 15626.
https://digitalcommons.njit.edu/fac_pubs/15626
