Induction of theta phase precession using a neurofeedback system.

The rodent hippocampus has been thought to represent the spatial environment as a cognitive map. The associative connections in the hippocampus imply that a neural entity represents the map as a geometrical network of hippocampal cells in terms of a chart. According to recent experimental observations, the cells fire successively relative to the theta oscillation of the local field potential, called theta phase precession, when the animal is running. This observation suggests the learning of temporal sequences with asymmetric connections in the hippocampus, but it also gives rather inconsistent implications on the formation of the chart that should consist of symmetric connections for space coding. In this study, we hypothesize that the chart is generated with theta phase coding through the integration of asymmetric connections. Our computer experiments use a hippocampal network model to demonstrate that a geometrical network is formed through running experiences in a few minutes. Asymmetric connections are found to remain and distribute heterogeneously in the network. The obtained network exhibits the spatial localization of activities at each instance as the chart does and their propagation that represents behavioral motions with multidirectional properties. We conclude that theta phase precession and the Hebbian rule with a time delay can provide the neural principles for learning the cognitive map.

Download Full-text

Memory Encoding by Theta Phase Precession in the Hippocampal Network

Neural Computation ◽

10.1162/089976603322362400 ◽

2003 ◽

Vol 15 (10) ◽

pp. 2379-2397 ◽

Cited By ~ 38

Author(s):

Naoyuki Sato ◽

Yoko Yamaguchi

Keyword(s):

Spike Timing ◽

Temporal Sequence ◽

Memory Storage ◽

Trial Experience ◽

Phase Precession ◽

Rate Coding ◽

Hippocampal Network ◽

Theta Phase ◽

Theta Phase Precession

Recent experimental evidence on spike-timing-dependent plasticity and on phase precession (i.e., the theta rhythm dependent firing of rat hippocampalcells) associates the contribution of phase precession to episodic memory. This article aims at clarifying the role of phase precession in memory storage. Computer simulations show that the memory storage in the behavioral timescale varies in timescale of the temporal sequence from half a second to several seconds. In contrast, the memory storage caused by traditional rate coding is restricted to the temporal sequence within 40 ms. During phase precession, memory storage of a single trial experience is possible, even in the presence of noise. It is therefore concluded that encoding by phase precession is appropriate for memory storage of the temporal sequence in the behavioral timescale.

Download Full-text

A model of hippocampal cell assembly dynamics based on single-cell theta phase precession

BMC Neuroscience ◽

10.1186/1471-2202-14-s1-p402 ◽

2013 ◽

Vol 14 (S1) ◽

Author(s):

Angus Chadwick ◽

Matthew F Nolan ◽

Mark CW Van Rossum

Keyword(s):

Single Cell ◽

Cell Assembly ◽

Hippocampal Cell ◽

Phase Precession ◽

Theta Phase ◽

Theta Phase Precession

Download Full-text

Transformation of Independent Oscillatory Inputs into Temporally Precise Rate Codes

10.1101/054163 ◽

2016 ◽

Author(s):

David Tingley ◽

Andrew A. Alexander ◽

Laleh K. Quinn ◽

Andrea A. Chiba ◽

Douglas Nitz

Keyword(s):

Field Potential ◽

Spatial Location ◽

Brain Regions ◽

Synaptic Activity ◽

Specific Rate ◽

Attention Task ◽

Potential Oscillations ◽

Phase Precession ◽

Theta Phase ◽

Theta Phase Precession

AbstractComplex behaviors demand temporal coordination among functionally distinct brain regions. The basal forebrain’s afferent and efferent structure suggests a capacity for mediating such coordination. During performance of a selective attention task, synaptic activity in this region was dominated by four amplitude-independent oscillations temporally organized by the phase of the slowest, a theta rhythm. Further, oscillatory amplitudes were precisely organized by task epoch and a robust input/output transform, from synchronous synaptic activity to spiking rates of basal forebrain neurons, was identified. For many neurons, spiking was temporally organized as phase precessing sequences against theta band field potential oscillations. Remarkably, theta phase precession advanced in parallel to task progression, rather than absolute spatial location or time. Together, the findings reveal a process by which associative brain regions can integrate independent oscillatory inputs and transform them into sequence-specific, rate-coded outputs that are adaptive to the pace with which organisms interact with their environment.

Download Full-text