Dynamics of Stochastic Neuronal Networks and the Connections to Random Graph Theory

Deville, Robert; Peskin, Charles S.; Spencer, Joel

doi:10.1051/mmnp/20105202

Cited by 15 publications

(59 citation statements)

References 51 publications

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“…With a view towards an eventual understanding of the interactions between complex networks and complicated dynamics, we study the evolution of discrete stochastic neuronal dynamics on these networks and the propensity of these dynamics to synchronize. The authors and collaborators have studied these exact dynamics on simpler graphs in [29,30], and the current work can be thought of an extension of those papers.…”

Section: Overviewmentioning

confidence: 99%

“…The purpose of this paper is to understand more fully the precise dependence of the synchronization properties of neuronal dynamics on the underlying networks on which they are defined. It was shown in [29,30] that random neuronal dynamics defined on "all-to-all" networks have certain interesting synchronization properties -in particular, in certain limits there exist discontinuous phase transitions between different attractors. We perform a comprehensive numerical study below, and show that, in a certain sense to be made precise below, while certain random topologies (e.g.…”

Section: Overviewmentioning

confidence: 99%

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Synchrony and Asynchrony for Neuronal Dynamics Defined on Complex Networks

Deville

Peskin

2011

Bull Math Biol

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We describe and analyze a model for a stochastic pulse-coupled neuronal network with many sources of randomness: random external input, potential synaptic failure, and random connectivity topologies. We show that different classes of network topologies give rise to qualitatively different types of synchrony: uniform (Erdős-Rényi) and "small-world" networks give rise to synchronization phenomena similar to that in "all-to-all" networks (in which there is a sharp onset of synchrony as coupling is increased); in contrast, in "scale-free" networks the dependence of synchrony on coupling strength is smoother. Moreover, we show that in the uniform and small-world cases, the fine details of the network are not important in determining the synchronization properties; this depends only on the mean connectivity. In marked contrast, for scale-free networks, the dynamics are significantly affected by the fine details of the network; in particular, they are significantly affected by the local neighborhoods of the "hubs" in the network.

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Section: Overviewmentioning

confidence: 99%

Section: Overviewmentioning

confidence: 99%

Synchrony and Asynchrony for Neuronal Dynamics Defined on Complex Networks

Deville

Peskin

2011

Bull Math Biol

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“…The first theme of this issue explores two lines of mathematical research that have been particularly fruitful: 1) neural synchronization [19,21], the fundamental process by which spatially distributed neural centers bind a sensory stimulus and coordinate their activities to respond to it, and 2) multistability [2,10,12], the concept that treatments may be possible by applying jolts of electricity to the right location in the brain at the right time [11,16]. Attention is drawn to the effects of time delays and random perturbations ("noise") on neural control and information processing.…”

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confidence: 99%

“…Obviously the most promising mechanisms for neural processing are those which are robust in the presence of noise and delay. In other words, it is not only necessary to develop analytical expressions that describe neural synchronization regardless of the number of neurons [5], it is also necessary to understand the effects of noise of the dynamics of synchronizing neural populations [2]. Similarly the widespread occurrence of time-delayed feedback in neural pathways raises questions as to the role of time delays in information processing [10] and whether new effects arise from the interplay between noise…”

mentioning

confidence: 99%

“…Brain-computer interfaces now make it possible to translate thought into action [6,7,8,15], replace lost limbs with robotic ones [9], prevent epileptic seizures [11,16] and even to alleviate the symptoms of neuro-degenerative diseases, such as Parkinson's [14]. Is it possible to do even better?The first theme of this issue explores two lines of mathematical research that have been particularly fruitful: 1) neural synchronization [19,21], the fundamental process by which spatially distributed neural centers bind a sensory stimulus and coordinate their activities to respond to it, and 2) multistability [2,10,12], the concept that treatments may be possible by applying jolts of electricity to the right location in the brain at the right time [11,16]. Attention is drawn to the effects of time delays and random perturbations ("noise") on neural control and information processing.…”

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confidence: 99%

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Quantitative Neuroscience: From Chalk Board to Bedside

Milton

2010

Math. Model. Nat. Phenom.

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Quantitative neuroscience, an interdisciplinary approach that brings together the mathematical, modeling, engineering and neuroscience communities, is rapidly bringing tangible hope of a better life to the tens of millions of people afflicted with diseases of the nervous system. The driving force is an increased understanding of how the nervous system exerts control and processes information.In less than 15 years, quantitative neuroscience is seemingly doing the impossible [12,17]. Brain-computer interfaces now make it possible to translate thought into action [6,7,8,15], replace lost limbs with robotic ones [9], prevent epileptic seizures [11,16] and even to alleviate the symptoms of neuro-degenerative diseases, such as Parkinson's [14]. Is it possible to do even better?The first theme of this issue explores two lines of mathematical research that have been particularly fruitful: 1) neural synchronization [19,21], the fundamental process by which spatially distributed neural centers bind a sensory stimulus and coordinate their activities to respond to it, and 2) multistability [2,10,12], the concept that treatments may be possible by applying jolts of electricity to the right location in the brain at the right time [11,16]. Attention is drawn to the effects of time delays and random perturbations ("noise") on neural control and information processing. Since axonal conduction velocities are finite, time delays are an intrinsic component of all neural feedback loops. Stochastic effects arise from fluctuations in ion channels and quantal release and from the convergence of multiple independent synaptic inputs. Obviously the most promising mechanisms for neural processing are those which are robust in the presence of noise and delay. In other words, it is not only necessary to develop analytical expressions that describe neural synchronization regardless of the number of neurons [5], it is also necessary to understand the effects of noise of the dynamics of synchronizing neural populations [2]. Similarly the widespread occurrence of time-delayed feedback in neural pathways raises questions as to the role of time delays in information processing [10] and whether new effects arise from the interplay between noise

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Population and Subpopulation Models

Greenwood

Ward

2016

Stochastic Neuron Models

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Dynamics of Stochastic Neuronal Networks and the Connections to Random Graph Theory

Cited by 15 publications

References 51 publications

Synchrony and Asynchrony for Neuronal Dynamics Defined on Complex Networks

Synchrony and Asynchrony for Neuronal Dynamics Defined on Complex Networks

Quantitative Neuroscience: From Chalk Board to Bedside

Population and Subpopulation Models

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