%A Ribeiro,Tiago L. %A Chialvo,Dante R. %A Plenz,Dietmar %D 2021 %J Frontiers in Systems Neuroscience %C %F %G English %K correlations,Criticality,Brain Dynamics,neuronal network,Flocking,scale-free,synchronization,mutual information %Q %R 10.3389/fnsys.2020.591210 %W %L %M %P %7 %8 2021-January-20 %9 Perspective %# %! Animal groups and neuronal populations %* %< %T Scale-Free Dynamics in Animal Groups and Brain Networks %U https://www.frontiersin.org/articles/10.3389/fnsys.2020.591210 %V 14 %0 JOURNAL ARTICLE %@ 1662-5137 %X Collective phenomena fascinate by the emergence of order in systems composed of a myriad of small entities. They are ubiquitous in nature and can be found over a vast range of scales in physical and biological systems. Their key feature is the seemingly effortless emergence of adaptive collective behavior that cannot be trivially explained by the properties of the system's individual components. This perspective focuses on recent insights into the similarities of correlations for two apparently disparate phenomena: flocking in animal groups and neuronal ensemble activity in the brain. We first will summarize findings on the spontaneous organization in bird flocks and macro-scale human brain activity utilizing correlation functions and insights from critical dynamics. We then will discuss recent experimental findings that apply these approaches to the collective response of neurons to visual and motor processing, i.e., to local perturbations of neuronal networks at the meso- and microscale. We show how scale-free correlation functions capture the collective organization of neuronal avalanches in evoked neuronal populations in nonhuman primates and between neurons during visual processing in rodents. These experimental findings suggest that the coherent collective neural activity observed at scales much larger than the length of the direct neuronal interactions is demonstrative of a phase transition and we discuss the experimental support for either discontinuous or continuous phase transitions. We conclude that at or near a phase-transition neuronal information can propagate in the brain with similar efficiency as proposed to occur in the collective adaptive response observed in some animal groups.