Exact neural mass model for synaptic-based working memory

Taher, Halgurd; Torcini, Alessandro; Olmi, Simona

doi:10.1371/journal.pcbi.1008533

Cited by 48 publications

(58 citation statements)

References 82 publications

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“…The low computational load enables the simulation of fMRI-like sessions in TVB. Future applications allow the possibility of including synaptic dynamics (Taher, Torcini, & Olmi, 2020), adaptation (Gast, Schmidt, & Knösche, 2020), excitatory versus inhibitory populations (Dumont & Gutkin, 2019; Laing, 2017; Montbrío et al, 2015), among others. The use of these models establishes a new venue to address multiscale phenomena, maintaining the co-existence of microscopic and macroscopic scales of organization (Coombes & Byrne, 2019).…”

Section: Discussionmentioning

confidence: 99%

Neuronal cascades shape whole-brain functional dynamics at rest

Rabuffo

Fousek

Bernard

et al. 2020

Preprint

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At rest, mammalian brains display a rich complex spatiotemporal behavior, which is reminiscent of healthy brain function and has provided nuanced understandings of several major neurological conditions. Despite the increasingly detailed phenomenological documentation of the brain’s resting state, its principle underlying causes remain unknown. To establish causality, we link structurally defined features of a brain network model to neural activation patterns and their variability. For the mouse, we use a detailed connectome-based model and simulate the resting state dynamics for neural sources and whole brain imaging signals (Blood-Oxygen-Level-Dependent (BOLD), Electroencephalography (EEG)). Under conditions of near-criticality, characteristic neuronal cascades form spontaneously and propagate through the network. The largest neuronal cascades produce short-lived but robust co-fluctuations at pairs of regions across the brain. During these co-activation episodes, long-lasting functional networks emerge giving rise to epochs of stable resting state networks correlated in time. Sets of neural cascades are typical for a resting state network, but different across. We experimentally confirm the existence and stability of functional connectivity epochs comprising BOLD co-activation bursts in mice (N=19). We further demonstrate the leading role of the neuronal cascades in a simultaneous EEG/fMRI data set in humans (N=15), explaining a large part of the variability of functional connectivity dynamics. We conclude that short-lived neuronal cascades are a major robust dynamic component contributing to the organization of the slowly evolving spontaneous fluctuations in brain dynamics at rest.

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Section: Discussionmentioning

confidence: 99%

Neuronal cascades shape whole-brain functional dynamics at rest

Rabuffo

Fousek

Bernard

et al. 2020

Preprint

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“…The presence of damped oscillations at the macroscopic level reflects the transitory synchronous firing of a fraction of the neurons in the ensemble. While this behavior is common in network models of spiking neurons, it is not captured by traditional firing-rate models (Schaffer et al, 2013 ; Devalle et al, 2017 ; Taher et al, 2020 ).…”

Section: Resultsmentioning

confidence: 99%

“…Furthermore, it has been successfully employed to reveal the mechanisms at the basis of theta-nested gamma oscillations (Ceni et al, 2020 ; Segneri et al, 2020 ) and the coexistence of slow and fast gamma oscillations (Bi et al, 2020 ). Finally, it has been recently applied to modeling electrical synapses (Montbrió and Pazó, 2020 ), working memory (Taher et al, 2020 ), the influence of transcranial magnetic stimulation on brain dynamics (Byrne et al, 2020 ), and brain resting state activity (Rabuffo et al, 2020 ).…”

Section: Discussionmentioning

confidence: 99%

“…The possibility to exactly move through the scales has not been fully exploited in this study, since we have focused the analysis on the extension of the single neural mass model to a multipopulation model, without adding other relevant features to the original model. However, it is possible to easily introduce, in the multipopulation model, biologically relevant characteristics, keeping intact the exact correspondence between microscopic and macroscopic scales, such as short-term synaptic plasticity (Taher et al, 2020 ), synaptic delays (Devalle et al, 2018 ), electrical coupling via gap junctions (Montbrió and Pazó, 2020 ), chemical synapses (Coombes and Byrne, 2019 ), and extrinsinc and endogenous noise (Goldobin et al, 2021 ). By adding short-term synaptic plasticity we expect to be able to reproduce the emergence of self-sustained activity in the high-activity state and, therefore, to describe a fully developed seizure.…”

Section: Discussionmentioning

confidence: 99%

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Patient-Specific Network Connectivity Combined With a Next Generation Neural Mass Model to Test Clinical Hypothesis of Seizure Propagation

Gerster

Taher

Škoch

et al. 2021

Front. Syst. Neurosci.

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Dynamics underlying epileptic seizures span multiple scales in space and time, therefore, understanding seizure mechanisms requires identifying the relations between seizure components within and across these scales, together with the analysis of their dynamical repertoire. In this view, mathematical models have been developed, ranging from single neuron to neural population. In this study, we consider a neural mass model able to exactly reproduce the dynamics of heterogeneous spiking neural networks. We combine mathematical modeling with structural information from non invasive brain imaging, thus building large-scale brain network models to explore emergent dynamics and test the clinical hypothesis. We provide a comprehensive study on the effect of external drives on neuronal networks exhibiting multistability, in order to investigate the role played by the neuroanatomical connectivity matrices in shaping the emergent dynamics. In particular, we systematically investigate the conditions under which the network displays a transition from a low activity regime to a high activity state, which we identify with a seizure-like event. This approach allows us to study the biophysical parameters and variables leading to multiple recruitment events at the network level. We further exploit topological network measures in order to explain the differences and the analogies among the subjects and their brain regions, in showing recruitment events at different parameter values. We demonstrate, along with the example of diffusion-weighted magnetic resonance imaging (dMRI) connectomes of 20 healthy subjects and 15 epileptic patients, that individual variations in structural connectivity, when linked with mathematical dynamic models, have the capacity to explain changes in spatiotemporal organization of brain dynamics, as observed in network-based brain disorders. In particular, for epileptic patients, by means of the integration of the clinical hypotheses on the epileptogenic zone (EZ), i.e., the local network where highly synchronous seizures originate, we have identified the sequence of recruitment events and discussed their links with the topological properties of the specific connectomes. The predictions made on the basis of the implemented set of exact mean-field equations turn out to be in line with the clinical pre-surgical evaluation on recruited secondary networks.

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“…It can be categorized into two main families, macroscopic models and microscopic models, according to the level of biological organization they aim to represent. The former one focuses on describing the mean activities (such as mean firing rates, mean postsynaptic potentials) of neuronal populations (6)(7)(8)(9). In contrast, the latter one focuses on quantifying the dynamical behavior of single neurons, which are considered to be the primary computational units of brain function (10)(11)(12)(13)(14)(15).…”

Section: Introductionmentioning

confidence: 99%

A model of metabolic supply-demand mismatch leading to secondary brain injury

Song

Kim

Struck

et al. 2021

Journal of Neurophysiology

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Secondary brain injury (SBI) is defined as new or worsening injury to the brain after an initial neurologic insult, such as hemorrhage, trauma, ischemic stroke, or infection. It is a common and potentially preventable complication following many types of primary brain injury (PBI). However, mechanistic details about how PBI leads to additional brain injury and evolves into SBI are poorly characterized. In this work, we propose a mechanistic model for the metabolic supply demand mismatch hypothesis (MSDMH) of SBI. Our model, based on the Hodgkin-Huxley model, supplemented with additional dynamics for extracellular potassium, oxygen concentration and excitotoxity, provides a high-level unified explanation for why patients with acute brain injury frequently develop SBI. We investigate how decreased oxygen, increased extracellular potassium, excitotoxicity, and seizures can induce SBI, and suggest three underlying paths for how events following PBI may lead to SBI. The proposed model also helps explain several important empirical observations, including the common association of acute brain injury with seizures, the association of seizures with tissue hypoxia and so on. In contrast to current practices which assume that ischemia plays the predominant role in SBI, our model suggests that metabolic crisis involved in SBI can also be non-ischemic. Our findings offer a more comprehensive understanding of the complex interrelationship among potassium, oxygen, excitotoxicity, seizures and SBI.

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Exact neural mass model for synaptic-based working memory

Cited by 48 publications

References 82 publications

Neuronal cascades shape whole-brain functional dynamics at rest

Neuronal cascades shape whole-brain functional dynamics at rest

Patient-Specific Network Connectivity Combined With a Next Generation Neural Mass Model to Test Clinical Hypothesis of Seizure Propagation

A model of metabolic supply-demand mismatch leading to secondary brain injury

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