Self-organization of a doubly asynchronous irregular network state for spikes and bursts

• Main Authors: Naud, R. (Author), Sprekeler, H. (Author), Vercruysse, F. (Author)
• Format: Article
• Language: English
• Published: Public Library of Science 2021
• Subjects: action potential; Action Potentials; animal; Animals; article; biological model; biology; Computational Biology; computer simulation; Computer Simulation; cytology; dendrite; Dendrites; homeostasis; Homeostasis; human cell; interneuron; Interneurons; learning; Models, Neurological; nerve cell network; nerve cell plasticity; Nerve Net; Neuronal Plasticity; physiology; Pyramidal Cells; pyramidal nerve cell; rat; Rats; spike
• Online Access: View Fulltext in Publisher
• ISBN: 1553734X (ISSN)
• DOI: 10.1371/journal.pcbi.1009478

Cortical pyramidal cells (PCs) have a specialized dendritic mechanism for the generation of bursts, suggesting that these events play a special role in cortical information processing. In vivo, bursts occur at a low, but consistent rate. Theory suggests that this network state increases the amount of information they convey. However, because burst activity relies on a threshold mechanism, it is rather sensitive to dendritic input levels. In spiking network models, network states in which bursts occur rarely are therefore typically not robust, but require fine-tuning. Here, we show that this issue can be solved by a homeostatic inhibitory plasticity rule in dendrite-targeting interneurons that is consistent with experimental data. The suggested learning rule can be combined with other forms of inhibitory plasticity to selforganize a network state in which both spikes and bursts occur asynchronously and irregularly at low rate. Finally, we show that this network state creates the network conditions for a recently suggested multiplexed code and thereby indeed increases the amount of information encoded in bursts. Copyright © 2021 Vercruysse et al.