Abstract
Neurons communicate primarily with spikes, but most theories of neural computation are based on firing rates. Yet, many experimental observations suggest that the temporal coordination of spikes plays a role in sensory processing. Among potential spike-based codes, synchrony appears as a good candidate because neural firing and plasticity are sensitive to fine input correlations. However, it is unclear what role synchrony may play in neural computation, and what functional advantage it may provide. With a theoretical approach, I show that the computational interest of neural synchrony appears when neurons have heterogeneous properties. In this context, the relationship between stimuli and neural synchrony is captured by the concept of synchrony receptive field, the set of stimuli which induce synchronous responses in a group of neurons. In a heterogeneous neural population, it appears that synchrony patterns represent structure or sensory invariants in stimuli, which can then be detected by postsynaptic neurons. The required neural circuitry can spontaneously emerge with spike-timing-dependent plasticity. Using examples in different sensory modalities, I show that this allows simple neural circuits to extract relevant information from realistic sensory stimuli, for example to identify a fluctuating odor in the presence of distractors. This theory of synchrony-based computation shows that relative spike timing may indeed have computational relevance, and suggests new types of neural network models for sensory processing with appealing computational properties.
Highlights
Neuronal synchronization is ubiquitous in the nervous system [1,2]
Numerous studies have shown that spike timing can convey information and that neurons are highly sensitive to synchrony in their inputs
I propose a simple spikebased computational framework, based on the idea that stimulus-induced synchrony can be used to extract sensory invariants, which is a difficult task for classical neural networks
Summary
Neuronal synchronization is ubiquitous in the nervous system [1,2]. In the retina, neighboring cells are often synchronized at a fine timescale [3,4], and relative spike timing carries information about visual stimuli [5]. At cellular level, modeling and experimental studies show that correlated inputs are more likely to make neurons fire [16,17,18,19], and synaptic plasticity mechanisms favor correlated synaptic inputs [20,21], so that developed neural circuits should be very sensitive to correlations. These findings suggest that neural synchronization is functionally important in early sensory pathways, but it is not clear what it implies in terms of computation
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