English

Self-organization without conservation: Are neuronal avalanches generically critical?

Disordered Systems and Neural Networks 2015-05-18 v1 Statistical Mechanics Computational Physics Neurons and Cognition

Abstract

Recent experiments on cortical neural networks have revealed the existence of well-defined avalanches of electrical activity. Such avalanches have been claimed to be generically scale-invariant -- i.e. power-law distributed -- with many exciting implications in Neuroscience. Recently, a self-organized model has been proposed by Levina, Herrmann and Geisel to justify such an empirical finding. Given that (i) neural dynamics is dissipative and (ii) there is a loading mechanism "charging" progressively the background synaptic strength, this model/dynamics is very similar in spirit to forest-fire and earthquake models, archetypical examples of non-conserving self-organization, which have been recently shown to lack true criticality. Here we show that cortical neural networks obeying (i) and (ii) are not generically critical; unless parameters are fine tuned, their dynamics is either sub- or super-critical, even if the pseudo-critical region is relatively broad. This conclusion seems to be in agreement with the most recent experimental observations. The main implication of our work is that, if future experimental research on cortical networks were to support that truly critical avalanches are the norm and not the exception, then one should look for more elaborate (adaptive/evolutionary) explanations, beyond simple self-organization, to account for this.

Keywords

Cite

@article{arxiv.1001.3256,
  title  = {Self-organization without conservation: Are neuronal avalanches generically critical?},
  author = {Juan A. Bonachela and Sebastiano de Franciscis and Joaquin J. Torres and Miguel A. Munoz},
  journal= {arXiv preprint arXiv:1001.3256},
  year   = {2015}
}

Comments

28 pages, 11 figures, regular paper

R2 v1 2026-06-21T14:36:30.422Z