Short-term plasticity based network model of place cells dynamics

Sandro Romani, Misha Tsodyks

Research output: Contribution to journalArticlepeer-review

Abstract

Rodent hippocampus exhibits strikingly different regimes of population activity in different behavioral states. During locomotion, hippocampal activity oscillates at theta frequency (5-12 Hz) and cells fire at specific locations in the environment, the place fields. As the animal runs through a place field, spikes are emitted at progressively earlier phases of the theta cycles. During immobility, hippocampus exhibits sharp irregular bursts of activity, with occasional rapid orderly activation of place cells expressing a possible trajectory of the animal. The mechanisms underlying this rich repertoire of dynamics are still unclear. We developed a novel recurrent network model that accounts for the observed phenomena. We assume that the network stores a map of the environment in its recurrent connections, which are endowed with short-term synaptic depression. We show that the network dynamics exhibits two different regimes that are similar to the experimentally observed population activity states in the hippocampus. The operating regime can be solely controlled by external inputs. Our results suggest that short-term synaptic plasticity is a potential mechanism contributing to shape the population activity in hippocampus.
Original languageEnglish
Pages (from-to)94-105
Number of pages12
JournalHippocampus
Volume25
Issue number1
Early online date25 Aug 2014
DOIs
StatePublished - Jan 2015

All Science Journal Classification (ASJC) codes

  • Cognitive Neuroscience

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