Synchronous firing frequency dependence in unidirectional coupled neuronal networks with chemical synapses

•Synchronized neural activity is relevant to function and disease in the brain.•The frequency of synchronous firing in local circuits in the brain depends on the properties of the synaptic connection that constitutes the local circuit.•Post-synaptic neurons coupled with excitatory and inhibitory syn...

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Bibliographic Details
Published in:Neurocomputing (Amsterdam) 2019-07, Vol.350, p.202-211
Main Authors: Ioka, Eri, Tsumoto, Kunichika, Kitajima, Hiroyuki
Format: Article
Language:English
Subjects:
Bifurcation analysis
Chemical synapses
Cortical neuron model
Frequency dependence
Phase synchronization
Synchronous firing
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Summary:•Synchronized neural activity is relevant to function and disease in the brain.•The frequency of synchronous firing in local circuits in the brain depends on the properties of the synaptic connection that constitutes the local circuit.•Post-synaptic neurons coupled with excitatory and inhibitory synapses tended to entrain high and low frequency firings, respectively, compared with pre-synaptic neurons.•We found that under relatively weak synaptic coupling strength constraints, the coupling function in a phase reduction model can be considered a one-parameter bifurcation diagram for phase synchronized responses. Rhythmic brain waves caused by the synchronous firing activity of neurons are believed to be relevant for higher brain functions such as the attention and sleep-wake state switching. In the brain, cortical neurons, including interneurons, are anatomically and functionally diverse and can fire at different frequencies. However, it still remains unclear how such cortical networks that comprise a variety of neurons create synchronous activity. The present study examined entrainments of firing activity in cortical networks. To explore how cortical networks causes synchronous firing and to elucidate the mechanism for synchronous activity, we performed numerical simulations of synchronous firing behaviors observed in a unidirectional coupled neuron model, mimicking one of the minimum motifs in cortical networks. Furthermore, we observed bifurcations of periodic oscillations, which cause various phase locking states, in the coupled neuron model. We analyzed these bifurcations to investigate the effects of differences in membrane excitability, synaptic properties, and model structural complexity on the synchronous firing frequency. We found that the post-synaptic neuron could more readily attain a phase locking state at higher or lower frequencies than the intrinsic firing frequency of the pre-synaptic neuron for excitatory and inhibitory synaptic inputs, respectively. This finding suggests that synaptic coupling properties might determine the entrainable frequency range (phase-locked range) of the synchronous firing behavior. Thus, the specific rhythmic waves evoked by brain activity may be attributable to the synaptic coupling properties constituting local circuits.
ISSN:0925-2312
1872-8286
DOI:10.1016/j.neucom.2019.03.034