Self-Organized Criticality in the Brain

Plenz, Dietmar; Ribeiro, Tiago L.; Miller, Stephanie R.; Kells, Patrick A.; Vakili, Ali; Capek, Elliott L.

doi:10.3389/fphy.2021.639389

Cited by 105 publications

(80 citation statements)

References 168 publications

(445 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Research with adults has also examined the differences in the energetic state of the brain between a resting and an attentive state. Generally, the resting state is associated with nearcritical dynamics, in which a high dynamic range and a large repertoire of brain states may be advantageous; whereas, a task-active (attentive) state induces subcritical dynamics, which is associated with a lower dynamic range, which in turn may reduce elements of interference affecting task performance (Fagerholm et al, 2015;Hellyer et al, 2014;Lynn et al, 2021;Plenz et al, 2021). According to the free energy minimisation principle, biological systems must resist the second law of thermodynamics (i.e., a tendency to disorder), so that they do not decay to equilibrium (K. Friston, 2010; K. J.…”

Section: Section 3 -Children Actively Sampling From the Environmentmentioning

confidence: 99%

Studying the developing brain in real-world contexts: moving from castles in the air to castles on the ground.

Wass¹,

Goupil²

2022

Preprint

View full text Add to dashboard Cite

Most current research in cognitive neuroscience uses reductionist, standardised experimental simulacra to study the developing brain. But these approaches do a poor job of mimicking the real-world, and thus can only provide a distorted picture of how cognitive operations and brain development unfold outside of the lab. Here we consider future research avenues which may lead to a better appreciation of how developing brains dynamically interact with a complex real-world environment, and how cognition develops over time. We raise several problems faced by current mainstream methods in the field, before briefly reviewing novel promising approaches that alleviate some of these issues. First, we consider research that examines passive perception by measuring entrainment between brain activity and temporal patterns in the environment. Second, we consider research that examines our ability to parse our continuous experience into discrete events, and how this ability develops over time. Third, we consider the role of children as active agents in selecting what they sample from the environment from one moment to the next. Fourth, we consider the potential of new approaches to measure how mutual influences between children and others are instantiated in suprapersonal brain networks. Finally, we discuss how we may reduce adult biases when designing developmental studies. Together, these approaches have great potential to further our understanding of how the developing brain learns to process information, and to control complex real-world behaviours.

show abstract

Section: Section 3 -Children Actively Sampling From the Environmentmentioning

confidence: 99%

Studying the developing brain in real-world contexts: moving from castles in the air to castles on the ground.

Wass¹,

Goupil²

2022

Preprint

View full text Add to dashboard Cite

show abstract

“…The role of such complex topologies in brain dynamics was pointed out [64]. Even though the brain data increasingly confirm the evidence of SOC, understanding the precise role of brain criticality remains a challenging question [65,66]. The underlying dilemma, as pointed out in a recent perspective paper [65], is whether the primary cause for the brain criticality lies in the demand of its robustness or improved functionality, both of which are compatible with SOC states.…”

Section: Self-organised Critical Systems and Their Network At Different Scalesmentioning

confidence: 99%

Self-Organised Critical Dynamics as a Key to Fundamental Features of Complexity in Physical, Biological, and Social Networks

Tadić

Melnik

2021

Dynamics

View full text Add to dashboard Cite

Studies of many complex systems have revealed new collective behaviours that emerge through the mechanisms of self-organised critical fluctuations. Subject to the external and endogenous driving forces, these collective states with long-range spatial and temporal correlations often arise from the intrinsic dynamics with the threshold nonlinearity and geometry-conditioned interactions. The self-similarity of critical fluctuations enables us to describe the system using fewer parameters and universal functions that, on the other hand, can simplify the computational and information complexity. Currently, the cutting-edge research on self-organised critical systems across the scales strives to formulate a unifying mathematical framework, utilise the critical universal properties in information theory, and decipher the role of hidden geometry. As a prominent example, we study the field-driven spin dynamics on the hysteresis loop in a network with higher-order structures described by simplicial complexes, which provides a geometric-frustration environment. While providing motivational illustrations from physical, biological, and social systems, along with their networks, we also demonstrate how the self-organised criticality occurs at the interplay of the complex topology and driving mode. This study opens up new promising routes with powerful tools to address a long-standing challenge in the theory and applications of complexity science ingrained in the efficient analysis of self-organised critical states under the competing higher-order interactions embedded in complex geometries.

show abstract

“…There are quite a few excellent reviews regarding the subject of brain criticality by now (see e.g., Wilting et al, 2018 ; Wilting and Priesemann, 2019a ; Plenz et al, 2021 ; Zeraati et al, 2021 ). But the field is full of controversies and clearly lacks a standardization.…”

Section: Introductionmentioning

confidence: 99%

Toward a Unified Analysis of the Brain Criticality Hypothesis: Reviewing Several Available Tools

2022

Front. Neural Circuits

View full text Add to dashboard Cite

The study of the brain criticality hypothesis has been going on for about 20 years, various models and methods have been developed for probing this field, together with large amounts of controversial experimental findings. However, no standardized protocol of analysis has been established so far. Therefore, hoping to make some contributions to standardization of such analysis, we review several available tools used for estimating the criticality of the brain in this paper.

show abstract

Self-Organized Criticality in the Brain

Cited by 105 publications

References 168 publications

Studying the developing brain in real-world contexts: moving from castles in the air to castles on the ground.

Studying the developing brain in real-world contexts: moving from castles in the air to castles on the ground.

Self-Organised Critical Dynamics as a Key to Fundamental Features of Complexity in Physical, Biological, and Social Networks

Toward a Unified Analysis of the Brain Criticality Hypothesis: Reviewing Several Available Tools

Contact Info

Product

Resources

About