Changes in functional connectivity preserve scale-free neuronal and behavioral dynamics
Anja Rabus, Davor Curic, Victorita E. Ivan, Ingrid M. Esteves, Aaron J. Gruber, Jörn Davidsen
Physical review. E November 2, 2023 DOI: 10.1103/physreve.108.l052301 via OpenAlex
Summary
AI-generated from the abstractThe brain may maintain optimal information transmission even when its functional connectivity is drastically altered. The psychedelic compound ibogaine, which induces an altered state of consciousness, fundamentally changes functional connectivity in the retrosplenial cortex of mice. Despite these changes, the scale-free statistics of movement and of neuronal avalanches among behaviorally related neurons remain largely unaltered. This suggests that the propagation of information within biological neural networks is robust to changes in the functional organization of neuronal subpopulations, offering a new perspective on how adaptive functional networks may support optimal information transmission.
Study at a glance
| Characteristics | Experimental study Peer reviewed |
|---|---|
| Population | Mice |
| Keywords | Neuroscience Information transmission Network dynamics Dynamic functional connectivity Consciousness |
| Citations | 8 |
| Key finding | Scale-free neuronal dynamics and self-similar features of behavioral dynamics persist following significant changes in functional connectivity induced by ibogaine. |
Abstract
Does the brain optimize itself for storage and transmission of information, and if so, how? The critical brain hypothesis is based in statistical physics and posits that the brain self-tunes its dynamics to a critical point or regime to maximize the repertoire of neuronal responses. Yet, the robustness of this regime, especially with respect to changes in the functional connectivity, remains an unsolved fundamental challenge. Here, we show that both scale-free neuronal dynamics and self-similar features of behavioral dynamics persist following significant changes in functional connectivity. Specifically, we find that the psychedelic compound ibogaine that is associated with an altered state of consciousness fundamentally alters the functional connectivity in the retrosplenial cortex of mice. Yet, the scale-free statistics of movement and of neuronal avalanches among behaviorally related neurons remain largely unaltered. This indicates that the propagation of information within biological neural networks is robust to changes in functional organization of subpopulations of neurons, opening up a new perspective on how the adaptive nature of functional networks may lead to optimality of information transmission in the brain.