Synchrony and Asynchrony for Neuronal Dynamics Defined on Complex Networks

Deville, Robert; Peskin, Charles S.

doi:10.1007/s11538-011-9674-0

Cited by 8 publications

(13 citation statements)

References 89 publications

(70 reference statements)

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“…We note that in, e.g. [9,10,11] (and in the present work), network nodes are to be interpreted as 'neural units' comprising many neurons, and representing a single cortical column, say. Detailed consideration of synaptic signalling models is therefore not appropriate.…”

Section: Introductionmentioning

confidence: 91%

“…Whilst actual estimates for mean degree in the rat cortex are not available, such connectivity is typical of that employed in the literature (see, e.g. [9,10,11] and references therein), particularly when one accounts for the large spread of observed degrees (e.g., for r = 0.35 the degree ranges from 8 to 48 whilst for r = 0.5 it lies between 20 and 87), and so serves to illustrate our methodology. For brevity, in the figures that follow, we illustrate the differences in spreading dynamics obtained in each network for the choices r = 0.35 and r = 0.5.…”

Section: Spreading Dynamicsmentioning

confidence: 99%

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Spreading dynamics on spatially constrained complex brain networks

O’Dea

Crofts

Kaiser

2013

J. R. Soc. Interface.

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The study of dynamical systems defined on complex networks provides a natural framework with which to investigate myriad features of neural dynamics and has been widely undertaken. Typically, however, networks employed in theoretical studies bear little relation to the spatial embedding or connectivity of the neural networks that they attempt to replicate. Here, we employ detailed neuroimaging data to define a network whose spatial embedding represents accurately the folded structure of the cortical surface of a rat brain and investigate the propagation of activity over this network under simple spreading and connectivity rules. By comparison with standard network models with the same coarse statistics, we show that the cortical geometry influences profoundly the speed of propagation of activation through the network. Our conclusions are of high relevance to the theoretical modelling of epileptic seizure events and indicate that such studies which omit physiological network structure risk simplifying the dynamics in a potentially significant way.

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Section: Introductionmentioning

confidence: 91%

Section: Spreading Dynamicsmentioning

confidence: 99%

Spreading dynamics on spatially constrained complex brain networks

O’Dea

Crofts

Kaiser

2013

J. R. Soc. Interface.

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“…Particular attention was frequently paid to which features of the phase response curve are conducive to synchrony [27]. We will be concerned with developing an inherently statistical approach applicable to all-excitatory networks [23,24,[29][30][31][32] that have stochastic driving and only a statistical description of their connectivity architecture.…”

Section: Introductionmentioning

confidence: 99%

“…A central advance presented in the present work therefore addresses the interplay between the network topology and the time-evolving ensemble of the neuronal membrane potentials that enables cascading total firing events to still take place with high probability in the appropriate parameter regimes. We are thereby attempting to contribute insight from another perspective to the broad question of how the statistical properties of the network are reflected in the statistical properties of the network dynamics [10,[32][33][34][35][36][37]. Moreover, we are here building a connection between our previous results concerning the statistical description of cascading total firing events in all-to-all coupled IF networks [30,31] with those addressing steady-state statistics of firing rates and membrane-potential correlations in the asynchronous operating regime of IF networks with specific nontrivial architectural connectivity [33].…”

Section: Introductionmentioning

confidence: 99%

Synchrony in stochastically driven neuronal networks with complex topologies

et al. 2015

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We study the synchronization of a stochastically driven, current-based, integrate-and-fire neuronal model on a preferential-attachment network with scale-free characteristics and high clustering. The synchrony is induced by cascading total firing events where every neuron in the network fires at the same instant of time. We show that in the regime where the system remains in this highly synchronous state, the firing rate of the network is completely independent of the synaptic coupling, and depends solely on the external drive. On the other hand, the ability for the network to maintain synchrony depends on a balance between the fluctuations of the external input and the synaptic coupling strength. In order to accurately predict the probability of repeated cascading total firing events, we go beyond mean-field and treelike approximations and conduct a detailed second-order calculation taking into account local clustering. Our explicit analytical results are shown to give excellent agreement with direct numerical simulations for the particular preferential-attachment network model investigated.

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“…To model systems in which transient cascades of two distinct and opposing influences can form, we extend the stochastic pulse-coupled neural network model of DeVille and Peskin192021; hereafter referred to as the DP model. First, by allowing each integrate-and-fire oscillator2223 to produce both positive and negative pulses that compel coupled oscillators to move closer to an upper or lower boundary (represented by distinct firing states), respectively.…”

mentioning

confidence: 99%

Cascades on a stochastic pulse-coupled network

Wray

Bishop

2014

Sci Rep

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While much recent research has focused on understanding isolated cascades of networks, less attention has been given to dynamical processes on networks exhibiting repeated cascades of opposing influence. An example of this is the dynamic behaviour of financial markets where cascades of buying and selling can occur, even over short timescales. To model these phenomena, a stochastic pulse-coupled oscillator network with upper and lower thresholds is described and analysed. Numerical confirmation of asynchronous and synchronous regimes of the system is presented, along with analytical identification of the fixed point state vector of the asynchronous mean field system. A lower bound for the finite system mean field critical value of network coupling probability is found that separates the asynchronous and synchronous regimes. For the low-dimensional mean field system, a closed-form equation is found for cascade size, in terms of the network coupling probability. Finally, a description of how this model can be applied to interacting agents in a financial market is provided.

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Synchrony and Asynchrony for Neuronal Dynamics Defined on Complex Networks

Cited by 8 publications

References 89 publications

Spreading dynamics on spatially constrained complex brain networks

Spreading dynamics on spatially constrained complex brain networks

Synchrony in stochastically driven neuronal networks with complex topologies

Cascades on a stochastic pulse-coupled network

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