Symmetry breaking organizes the brain's resting state manifold

Fousek, J.; Rabuffo, Giovanni; Gudibanda, Kashyap; Sheheitli, Hiba; Jirsa, Viktor; Petkoski, Spase

doi:10.1101/2022.01.03.474841

Cited by 7 publications

(9 citation statements)

References 81 publications

(105 reference statements)

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“…Fluidity captures the recurring patterns of co-activation across time and, more specifically, the switches between highly correlated and non-correlated patterns. Even though direct evidence is sparse due to challenges in probing human brain activity’s manifold, fluidity is believed to reflect the complexity of the energy landscape and the number of attractors(13, 28). The distribution of fluidity in the model’s parameter space (Fig 2c top-left) shows a peak near the working point value, reflecting recurring cascades during simulation, and decreases monotonously as the regime is drawn away from it.…”

Section: Resultsmentioning

confidence: 99%

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Spatiotemporal brain complexity quantifies consciousness outside of perturbation paradigms

Breyton

Fousek

Rabuffo

et al. 2023

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Neural bases of consciousness have been explored through many different paradigms and the notion of complexity emerged as a unifying framework to characterize conscious experience. To date, the perturbational complexity index (PCI), rooted on information theory, shows high performance in assessing consciousness. However, the mechanisms underpinning this perturbational complexity remain unclear as well as its counterpart in spontaneous activity. In the present study, we explore brain responsiveness and resting-state activity through large-scale brain modeling and prove that complexity and consciousness are directly associated with a fluid dynamical regime. This fluidity is reflected in the dynamic functional connectivity, and other metrics drawn from dynamical systems theory and manifolds can capture such dynamics in synthetic data. We then validate our findings on a cohort of 15 subjects under anesthesia and wakefulness and show that measures of fluidity on spontaneous activity can distinguish consciousness in agreement with perturbational complexity.

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Section: Resultsmentioning

confidence: 99%

“…Yet these coactivations patterns are not purely stochastic (27). They are often repetitive, revisiting the same neighborhood in state space (28).…”

Section: Large-scale Brain Model and Dynamical Regimesmentioning

confidence: 99%

Spatiotemporal brain complexity quantifies consciousness outside of perturbation paradigms

Breyton

Fousek

Rabuffo

et al. 2023

Preprint

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“…Another question is what the mechanistic origin could be of the observed spatio-temporal complexity of dFC (and of its alterations). Previous studies have shown that structured dFC may emerge as an effect of global brain network dynamics to be tuned at a slightly subcritical working point (Arbabyazd et al, 2020; Glomb et al, 2017; Hansen et al, 2015), or as a consequence of cascades of neuronal activations (Rabuffo et al, 2021) that occur due to the flow on the manifold created by the symmetry breaking of the connectome (Fousek et al, 2022). However, these studies did not use very precise criteria when referring to their capacity to render dFC.…”

Section: Discussionmentioning

confidence: 99%

State switching and high-order spatiotemporal organization of dynamic Functional Connectivity are disrupted by Alzheimer’s Disease

Arbabyazd

Petkoski

Breakspear

et al. 2023

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Spontaneous activity during the resting state, tracked by BOLD fMRI imaging, or shortly rsfMRI, gives rise to brain-wide dynamic patterns of inter-regional correlations, whose structured flexibility relates to cognitive performance. Here we analyze resting state dynamic Functional Connectivity (dFC) in a cohort of older adults, including amnesic Mild Cognitive Impairment (aMCI, N = 34) and Alzheimer's Disease (AD, N = 13) patients, as well as normal control (NC, N = 16) and cognitively "super-normal" (SN, N = 10) subjects. Using complementary state-based and state-free approaches, we find that resting state fluctuations of different functional links are not independent but are constrained by high-order correlations between triplets or quadruplets of functionally connected regions. When contrasting patients with healthy subjects, we find that dFC between cingulate and other limbic regions is increasingly bursty and intermittent when ranking the four groups from SNC to NC, aMCI and AD. Furthermore, regions affected at early stages of AD pathology are less involved in higher-order interactions in patient than in control groups, while pairwise interactions are not significantly reduced. Our analyses thus suggest that the spatiotemporal complexity of dFC organization is precociously degraded in AD and provides a richer window into the underlying neurobiology than time-averaged FC connections.

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“…By coupling the brain regions via an additive current in the average membrane potential equations, the dynamics of the whole-brain network can be described as follows (Rabuffo et al, 2021; Fousek et al, 2022): where G is the network scaling parameter that modulates the overall impact of brain connectivity on the state dynamics (see Supplementary, Fig S1), SC i,j denotes the symmetrical connection weight between i th and j th nodes with i, j ∈ { 1, 2, …, N } , and the dynamical noise ξ( t ) ∼ 𝒩 (0, σ 2 ) follows a Gaussian distribution with mean zero and variance σ 2 = 0.03. The brain network model was implemented in TVB software (Sanz Leon et al, 2013; Rabuffo et al, 2021) and equipped with BOLD forward solution comprising the Balloon-Windkessel model (Stephan et al, 2007) applied to the firing rate.…”

Section: Methodsmentioning

confidence: 99%

“…The input current I stim represents the stimulation to selected brain regions, which increase the basin of attraction of the up-state in comparison to the down-state, while the fixed points move farther apart (Rabuffo et al, 2021). By coupling the brain regions via an additive current in the average membrane potential equations, the dynamics of the whole-brain network can be described as follows (Rabuffo et al, 2021;Fousek et al, 2022):…”

Section: The Virtual Brain Modelsmentioning

confidence: 99%

Probabilistic Inference on Virtual Brain Models of Disorders

Hashemi,

Ziaeemehr,

Woodman

et al. 2024

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Connectome-based models, also known as Virtual Brain Models (VBMs), have been well established in network neuroscience to investigate pathophysiological causes underlying a large range of brain diseases. The integration of an individual’s brain imaging data in VBMs has improved patient-specific predictivity, although Bayesian estimation of spatially distributed parameters remains challenging even with state-of-the-art Monte Carlo sampling. VBMs imply latent nonlinear state space models driven by noise and network input, necessitating advanced probabilistic machine learning techniques for widely applicable Bayesian estimation. Here we present Simulation-Based Inference on Virtual Brain Models (SBI-VBMs), and demonstrate that training deep neural networks on both spatio-temporal and functional features allows for accurate estimation of generative parameters in brain disorders. The systematic use of brain stimulation provides an effective remedy for the non-identifiability issue in estimating the degradation of intra-hemispheric connections. By prioritizing model structure over data, we show that the hierarchical structure in SBI-VBMs renders the inference more effective, precise and biologically plausible. This approach could broadly advance precision medicine by enabling fast and reliable prediction of patient-specific brain disorders.

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Symmetry breaking organizes the brain's resting state manifold

Cited by 7 publications

References 81 publications

Spatiotemporal brain complexity quantifies consciousness outside of perturbation paradigms

Spatiotemporal brain complexity quantifies consciousness outside of perturbation paradigms

State switching and high-order spatiotemporal organization of dynamic Functional Connectivity are disrupted by Alzheimer’s Disease

Probabilistic Inference on Virtual Brain Models of Disorders

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