Modular Architecture Facilitates Noise-driven Control of Synchrony in Neuronal Networks

Overview

Journal Sci Adv

Specialties Biology
Science

Date 2023 Aug 25

PMID 37624893

Authors

Hideaki Yamamoto

F Paul Spitzner

Taiki Takemuro

Victor Buendia

Hakuba Murota

Carla Morante

Tomohiro Konno

Shigeo Sato

Ayumi Hirano-Iwata

Anna Levina

Viola Priesemann

Miguel A Munoz

Johannes Zierenberg

Jordi Soriano

Affiliations

Soon will be listed here.

Abstract

High-level information processing in the mammalian cortex requires both segregated processing in specialized circuits and integration across multiple circuits. One possible way to implement these seemingly opposing demands is by flexibly switching between states with different levels of synchrony. However, the mechanisms behind the control of complex synchronization patterns in neuronal networks remain elusive. Here, we use precision neuroengineering to manipulate and stimulate networks of cortical neurons in vitro, in combination with an in silico model of spiking neurons and a mesoscopic model of stochastically coupled modules to show that (i) a modular architecture enhances the sensitivity of the network to noise delivered as external asynchronous stimulation and that (ii) the persistent depletion of synaptic resources in stimulated neurons is the underlying mechanism for this effect. Together, our results demonstrate that the inherent dynamical state in structured networks of excitable units is determined by both its modular architecture and the properties of the external inputs.

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