Scaling properties of neuronal avalanches are consistent with critical dynamics

TL;DR

This study provides experimental evidence that neuronal avalanches exhibit multiple properties consistent with critical dynamics, supporting the hypothesis that the brain operates near a critical point for optimal adaptability and information processing.

Contribution

The paper demonstrates five fundamental properties of neuronal avalanches that align with criticality, extending previous size and duration analyses to include temporal and spatial scaling behaviors.

Findings

Avalanche size and lifetime distributions are invariant to external driving.

Avalanches follow Omori law before and after main events.

Spatial spread of avalanches exhibits fractal and finite-size scaling.

Abstract

Complex systems, when poised near a critical point of a phase transition between order and disorder, exhibit a dynamics comprising a scale-free mixture of order and disorder which is universal, i.e. system-independent (1-5). It allows systems at criticality to adapt swiftly to environmental changes (i.e., high susceptibility) as well as to flexibly process and store information. These unique properties prompted the conjecture that the brain might operate at criticality (1), a view supported by the recent description of neuronal avalanches in cortex in vitro (6-8), in anesthetized rats (9) and awake primates (10), and in neuronal models (11-16). Despite the attractiveness of this idea, its validity is hampered by the fact that its theoretical underpinning relies solely on the replication of sizes and durations of avalanches, which reflect only a portion of the rich dynamics found at criticality. Here we show experimentally five fundamental properties of avalanches consistent with criticality: (1) a separation of time scales, in which the power law probability density of avalanches sizes s, P(s) and the lifetime distribution of avalanches are invariant to slow, external driving; (2) stationary P(s) over time; (3) the avalanche probabilities preceding and following main avalanches obey Omori law (17, 18) for earthquakes; (4) the average size of avalanches following a main avalanche decays as a power law; (5) the spatial spread of avalanches has a fractal dimension and obeys finite-size scaling. Thus, neuronal avalanches are a robust manifestation of criticality in the brain.