Videos

Noise and collective activity patterns of neuronal networks

Presenter
February 25, 2016
Abstract
Multielectrode recordings have revealed complex and coordinated population activity in neuronal networks. Among the variety of reported patterns, a central regime of synchronous activity is thought to serve important function and the disruptions of which could be associated to serious condition. A more debated regime is concerned with the distribution of avalanches, defined as chunks of population activity separated by silences, in population (LFPs) or spike recordings; power-law distributions of avalanches are sometimes interpreted as revealing that the brain functions at a critical regime. I will present some thoughts and mathematical developments on simple models of large-scale stochastic networks, in order to uncover the complex interplay between stochastic and nonlinear dynamics in the emergence of these regimes. I will show that network structure, as well as increased noise levels, interact with nonlinear neurons activity to induce synchronization in large-scale systems, a phenomenon already reported in the biological literature on epilepsy. As for avalanche analysis, we will show that the data analysis methods used do not univocally reveal the presence of criticality: power-law scalings in LFPs avalanches may only be due to the noise in the LFP recordings, and power-laws in spiking data to Boltzmann’s molecular chaos (or propagation of chaos), a universal phenomenon in statistical systems.