Griffiths phases and the stretching of criticality in brain networks

TL;DR

This paper demonstrates that the hierarchical and modular structure of brain networks creates an extended critical-like region called a Griffiths phase, which enhances brain function and self-organization without requiring fine-tuning.

Contribution

It reveals that brain network architecture leads to Griffiths phases, broadening the critical region and improving functional robustness and adaptability.

Findings

Griffiths phases found in synthetic and empirical brain networks

Extended critical regions facilitate self-organization and adaptation

Structural disorder enhances brain network functionality

Abstract

Hallmarks of criticality, such as power-laws and scale invariance, have been empirically found in cortical networks and it has been conjectured that operating at criticality entails functional advantages, such as optimal computational capabilities, memory, and large dynamical ranges. As critical behavior requires a high degree of fine tuning to emerge, some type of self-tuning mechanism needs to be invoked. Here we show that, taking into account the complex hierarchical-modular architecture of cortical networks, the singular critical point is replaced by an extended critical-like region which corresponds --in the jargon of statistical mechanics-- to a Griffiths phase. Using computational and analytical approaches, we find Griffiths phases in synthetic hierarchical networks and also in empirical brain networks such as the human connectome and the caenorhabditis elegans one. Stretched critical regions, stemming from structural disorder, yield enhanced functionality in a generic way, facilitating the task of self-organizing, adaptive, and evolutionary mechanisms selecting for criticality.