A neuronal learning rule for sub-millisecond temporal coding

A PARADOX that exists in auditory and electrosensory neural systems 1,2 is that they encode behaviourally relevant signals in the range of a few microseconds with neurons that are at least one order of magnitude slower. The importance of temporal coding in neural information processing is not clear...

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Bibliographic Details
Published in:Nature (London) 1996-09, Vol.383 (6595), p.76-78
Main Authors: Gerstner, Wulfram, Kempter, Richard, van Hemmen, J. Leo, Wagner, Hermann
Format: Article
Language:English
Subjects:
Animals
Auditory Pathways
Auditory Perception - physiology
Birds
Computer Simulation
Ears & hearing
Hearing - physiology
Humanities and Social Sciences
letter
Membrane Potentials
multidisciplinary
Neurons
Neurons, Afferent - physiology
Owls
Reaction Time
Science
Science (multidisciplinary)
Simulation
Synapses - physiology
Tyto alba
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Summary:A PARADOX that exists in auditory and electrosensory neural systems 1,2 is that they encode behaviourally relevant signals in the range of a few microseconds with neurons that are at least one order of magnitude slower. The importance of temporal coding in neural information processing is not clear yet 3–8 . A central question is whether neuronal firing can be more precise than the time constants of the neuronal processes involved 9 . Here we address this problem using the auditory system of the barn owl as an example. We present a modelling study based on computer simulations of a neuron in the laminar nucleus. Three observations explain the paradox. First, spiking of an 'integrate-and-fire' neuron driven by excitatory postsynaptic potentials with a width at half-maximum height of 250 μs, has an accuracy of 25 μs if the presynaptic signals arrive coherently. Second, the necessary degree of coherence in the signal arrival times can be attained during ontogenetic development by virtue of an unsupervised hebbian learning rule. Learning selects connections with matching delays from a broad distribution of axons with random delays. Third, the learning rule also selects the correct delays from two independent groups of inputs, for example, from the left and right ear.
ISSN:0028-0836
1476-4687
DOI:10.1038/383076a0