Criticality and network structure drive emergent oscillations in a stochastic whole-brain model

Barzon, Giacomo; Nicoletti, Giorgio; Mariani, Benedetta; Formentin, Marco; Suweis, Samir

doi:10.1088/2632-072x/ac7a83

Cited by 9 publications

(4 citation statements)

References 58 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…While the authors of another study simulating Ising dynamics on connectomes 47 hypothesize that structural connectivity alone cannot explain some effects observed in functional correlations of patients after severe brain injuries, no other explanation has been provided in the literature. Our explanation of the anomalous behavior of the cluster-based indicator of criticality, on the other hand, is consistent with the distinction 51 , 52 between well-known structurally-driven percolation phase transitions and dynamic transitions-for which less is known 36 . Reframed in these terms, our results would suggest that in brain strokes there is no change in whatever underlies dynamic transitions, but that there are structural changes that could disorganize the percolation-like transitions.…”

Section: Discussionsupporting

confidence: 86%

Investigating structural and functional aspects of the brain’s criticality in stroke

Janarek,

Drogosz,

Grela

et al. 2023

Sci Rep

View full text Add to dashboard Cite

This paper addresses the question of the brain’s critical dynamics after an injury such as a stroke. It is hypothesized that the healthy brain operates near a phase transition (critical point), which provides optimal conditions for information transmission and responses to inputs. If structural damage could cause the critical point to disappear and thus make self-organized criticality unachievable, it would offer the theoretical explanation for the post-stroke impairment of brain function. In our contribution, however, we demonstrate using network models of the brain, that the dynamics remain critical even after a stroke. In cases where the average size of the second-largest cluster of active nodes, which is one of the commonly used indicators of criticality, shows an anomalous behavior, it results from the loss of integrity of the network, quantifiable within graph theory, and not from genuine non-critical dynamics. We propose a new simple model of an artificial stroke that explains this anomaly. The proposed interpretation of the results is confirmed by an analysis of real connectomes acquired from post-stroke patients and a control group. The results presented refer to neurobiological data; however, the conclusions reached apply to a broad class of complex systems that admit a critical state.

show abstract

Section: Discussionsupporting

confidence: 86%

Investigating structural and functional aspects of the brain’s criticality in stroke

Janarek,

Drogosz,

Grela

et al. 2023

Sci Rep

View full text Add to dashboard Cite

show abstract

“…From a broader perspective, our findings document power law scaling of neural activity during language processing in the newborn brain. This statistical property is a hallmark of critical phenomena, and it has been suggested that criticality in the brain is linked to states of optimal information transmission and storage (49)(50)(51)(52). The newborn brain may thus already be in an optimal state for the efficient processing of speech and language, underpinning human infants' unexpected language learning abilities.…”

Section: Discussionmentioning

confidence: 99%

Prenatal experience with language shapes the brain

Mariani,

Nicoletti,

Barzon

et al. 2023

Sci. Adv.

Self Cite

View full text Add to dashboard Cite

Human infants acquire language with notable ease compared to adults, but the neural basis of their remarkable brain plasticity for language remains little understood. Applying a scaling analysis of neural oscillations to address this question, we show that newborns’ electrophysiological activity exhibits increased long-range temporal correlations after stimulation with speech, particularly in the prenatally heard language, indicating the early emergence of brain specialization for the native language.

show abstract

“…Schwalger et coauthors proposed a system of equations for several interacting populations at the mesoscopic scale, starting from a microscopic model of randomly connected generalized integrateand-fire neuron models for networks varying between 50-2000 neurons [5]. In turn, in [6], it was shown that structural networks are a crucial component of the stochastic brain model on the mesoscopic scale. A metric called multiscale relevance (MSR) was proposed in [7] to capture the dynamic variability of the activity of single neurons across different scales.…”

Section: Introductionmentioning

confidence: 99%

Does Adding of Neurons to the Network Layer Lead to Increased Transmission Efficiency?

Paprocki,

Pregowska,

Szczepanski

2024

IEEE Access

View full text Add to dashboard Cite

The aim of this study is to contribute to the important question in Neuroscience of whether the number of neurons in a given layer of network affects a transmission efficiency. Mutual Information, as defined by Shannon, between the input and output signals for certain classes of networks is analyzed theoretically and numerically. A Levy-Baxter probabilistic neural model is applied. This model includes all important qualitative mechanisms involved in the transmission process in the brain. We derived analytical formulas for the Mutual Information of input signals coming from Information Sources as Bernoulli processes. These formulas depend on the parameters of the Information Source, neuron and network. Numerical simulations were performed using these equations. It turned out, that the Mutual Information starting from a certain value increases very slowly with the number of neurons being added. The increase is of the rate m − c where m is the number of neurons in the transmission layer, and c is very small. The calculations also show that for a practical number (up to 15000) of neurons, the Mutual Information reaches only approximately half of the information that is carried out by the input signal. The influence of noise on the transmission efficiency depending on the number of neurons was also analyzed. It turned out that the noise level at which transmission is optimal increases significantly with this number. Our results indicate that a large number of neurons in the network does not generally indicate an essential improvement in transmission efficiency, but can contribute to reliability.INDEX TERMS Shannon communication theory; neural network; transmission efficiency; mutual information; model of neuron, spike trains, information source, entropy.

show abstract

Criticality and network structure drive emergent oscillations in a stochastic whole-brain model

Cited by 9 publications

References 58 publications

Investigating structural and functional aspects of the brain’s criticality in stroke

Investigating structural and functional aspects of the brain’s criticality in stroke

Prenatal experience with language shapes the brain

Does Adding of Neurons to the Network Layer Lead to Increased Transmission Efficiency?

Contact Info

Product

Resources

About