Deconstructing scale-free neuronal avalanches: behavioral transitions and neuronal response

Curic, Davor; Ivan, Victorita E.; Cuesta, David T; Esteves, Ingrid M.; Mohajerani, Majid H.; Gruber, Aaron J.; Davidsen, Jörn

doi:10.1088/2632-072x/ac35b4

Cited by 11 publications

(12 citation statements)

References 58 publications

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“…Avalanche events and quiescent periods between events were detected according to previous work ( 35 ) ( Figure 3A ; see Supplemental Methods ). Briefly, activity was binned and summed across all units.…”

Section: Resultsmentioning

confidence: 88%

The Nonclassic Psychedelic Ibogaine Disrupts Cognitive Maps

Ivan,

Tomàs-Cuesta,

Esteves

et al. 2024

Biological Psychiatry Global Open Science

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Section: Resultsmentioning

confidence: 88%

The Nonclassic Psychedelic Ibogaine Disrupts Cognitive Maps

Ivan,

Tomàs-Cuesta,

Esteves

et al. 2024

Biological Psychiatry Global Open Science

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“…These collective signals represent an aggregate of the underlying spike activity of many individual neurons. However, when spikes recorded in awake animals have been analyzed directly, results have been less clear—some studies report support for criticality ( 34 , 36 , 38 – 42 , 49 , 75 ) while others do not ( 30 – 35 ). Considering that spikes are the fundamental information carriers underlying brain function, the equivocal support for criticality at the level of spike measurements has created skepticism and confusion surrounding the hypothesis ( 32 , 33 ).…”

Section: Discussionmentioning

confidence: 99%

Low-dimensional criticality embedded in high-dimensional awake brain dynamics

Fontenele,

Sooter,

Norman

et al. 2024

Sci. Adv.

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Whether cortical neurons operate in a strongly or weakly correlated dynamical regime determines fundamental information processing capabilities and has fueled decades of debate. We offer a resolution of this debate; we show that two important dynamical regimes, typically considered incompatible, can coexist in the same local cortical circuit by separating them into two different subspaces. In awake mouse motor cortex, we find a low-dimensional subspace with large fluctuations consistent with criticality—a dynamical regime with moderate correlations and multi-scale information capacity and transmission. Orthogonal to this critical subspace, we find a high-dimensional subspace containing a desynchronized dynamical regime, which may optimize input discrimination. The critical subspace is apparent only at long timescales, which explains discrepancies among some previous studies. Using a computational model, we show that the emergence of a low-dimensional critical subspace at large timescales agrees with established theory of critical dynamics. Our results suggest that the cortex leverages its high dimensionality to multiplex dynamical regimes across different subspaces.

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“…To tackle this challenge, we studied the robustness of neuronal and behavioral dynamics to changes in FC in mouse retrosplenial cortex (RSC), an area of the brain well positioned to integrate sensory, mnemonic, and cognitive information by virtue of its strong connectivity with the hippocampus, medial prefrontal cortex, and primary sensory cortices. As shown in [34–37], a subset of RSC neurons increase neural activity during movement, while another decreases activity. In the present study, we perturbed these functional networks using the psychedelic drug ibogaine.…”

mentioning

confidence: 95%

Changes in functional connectivity preserve scale-free neuronal and behavioral dynamics

Rabus,

Curic,

Ivan

et al. 2023

Preprint

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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 sub-populations 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.

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Deconstructing scale-free neuronal avalanches: behavioral transitions and neuronal response

Cited by 11 publications

References 58 publications

The Nonclassic Psychedelic Ibogaine Disrupts Cognitive Maps

The Nonclassic Psychedelic Ibogaine Disrupts Cognitive Maps

Low-dimensional criticality embedded in high-dimensional awake brain dynamics

Changes in functional connectivity preserve scale-free neuronal and behavioral dynamics

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