Signal Propagation and Logic Gating in Networks of Integrate-and-Fire Neurons

Transmission of signals within the brain is essential for cognitive function, but it is not clear how neural circuits support reliable and accurate signal propagation over a sufficiently large dynamic range. Two modes of propagation have been studied: synfire chains, in which synchronous activity tr...

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Bibliographic Details
Published in:The Journal of neuroscience 2005-11, Vol.25 (46), p.10786-10795
Main Authors: Vogels, Tim P, Abbott, L. F
Format: Article
Language:English
Subjects:
Action Potentials - physiology
Behavioral/Systems/Cognitive
Ion Channel Gating - physiology
Logic
Models, Neurological
Neural Networks (Computer)
Neural Pathways - physiology
Neurons - physiology
Signal Transduction - physiology
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Summary:Transmission of signals within the brain is essential for cognitive function, but it is not clear how neural circuits support reliable and accurate signal propagation over a sufficiently large dynamic range. Two modes of propagation have been studied: synfire chains, in which synchronous activity travels through feedforward layers of a neuronal network, and the propagation of fluctuations in firing rate across these layers. In both cases, a sufficient amount of noise, which was added to previous models from an external source, had to be included to support stable propagation. Sparse, randomly connected networks of spiking model neurons can generate chaotic patterns of activity. We investigate whether this activity, which is a more realistic noise source, is sufficient to allow for signal transmission. We find that, for rate-coded signals but not for synfire chains, such networks support robust and accurate signal reproduction through up to six layers if appropriate adjustments are made in synaptic strengths. We investigate the factors affecting transmission and show that multiple signals can propagate simultaneously along different pathways. Using this feature, we show how different types of logic gates can arise within the architecture of the random network through the strengthening of specific synapses.
ISSN:0270-6474
1529-2401
DOI:10.1523/JNEUROSCI.3508-05.2005