Burst synchronization transitions in a neuronal network of subnetworks

Sun, Xiaojuan; Lei, Jinzhi; Perc, Matjaž; Kurths, Jürgen; Chen, Guanrong

doi:10.1063/1.3559136

Cited by 172 publications

(77 citation statements)

References 60 publications

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“…Firing patterns in the excitatory synaptic coupled preBötC neurons exhibit in-phase and anti-phase bursting (or spiking) under different initial conditions (Sun et al 2011). When the initial conditions for two-coupled neurons are same, the system will exhibit in-phase bursting.…”

Section: Model Descriptionmentioning

confidence: 99%

“…Smith et al further investigated the frequency control and synchronization of these model neurons when coupled by excitatory synapses, simulations of pairs of identical cells revealed that increasing tonic excitation increases the frequency of synchronous bursting (Butera et al 1999b). Bursting and complex synchronous behaviors are important aspects in the study of rhythm dynamics of complex neuronal system (Wang et al 2011;Guo et al 2012;Sun et al 2011;Perc and Marhl 2004a, b).…”

Section: Introductionmentioning

confidence: 99%

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Dynamics of in-phase and anti-phase bursting in the coupled pre-Bötzinger complex cells

et al. 2016

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Activity of neurons in the pre-Bötzinger complex within the mammalian brain stem has an important role in the generation of respiratory rhythms. Previous experimental results have shown that the dynamics of sodium and calcium within each cell may be responsible for various bursting mechanisms. In this paper, we study the bursting dynamics of the two-coupled pre-Bötzinger complex neurons. Using a combination of fast-slow decomposition and two-parameter bifurcation analysis, we explore the possible forms of dynamics that the model network can produce as well the transitions of in-phase and anti-phase bursting respectively.

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Section: Model Descriptionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Dynamics of in-phase and anti-phase bursting in the coupled pre-Bötzinger complex cells

et al. 2016

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“…Based on the wellknown neuron models, networks with different topological connections have been set to investigate the synchronization stability [36,37], pattern selection, and mode transition in collective behaviors [38][39][40][41][42][43][44][45]. Indeed, reliable and biophysical neuron model is critical and important for further investigation on neurodynamics and potential mechanism of some neuronal diseases [46].…”

Section: Complexitymentioning

confidence: 99%

Autaptic Modulation of Electrical Activity in a Network of Neuron-Coupled Astrocyte

Guo

Tang

et al. 2017

Complexity

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Autapse connection is considered on a biological neuron coupled by astrocyte, and the effect of autapse driving-induced response in electrical activities is investigated. In this paper, a simple network is developed on the Hodgkin-Huxley (HH) neuron coupled by astrocyte and the autapse effect is also considered. The modulation of autapse connected to HH neuron can change the membrane potential by applying time-delayed feedback along a close loop. It is found that the self-adaption of autapse driving can make the network of neuron-astrocyte generate different modes of electrical activities, and oscillating behavior of Ca 2+ and IP 3 setting is controlled. This new network model can give potential understanding about self-adaption of neuron to external forcing when the coupling of astrocyte and autapse is considered.

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“…Synchronization, as an emerging phenomenon of a population of dynamically interacting units (Arenas et al 2008;Wang and Jiao 2006;Wang and Zhang 2003;Zhang et al 2010), has been extensively studied both in coupled cells (Wang et al 2011;Marek and Stuchl 1975) or complex networks (Gomez-Gardenes et al 2007;Volman et al 2011;Sun et al 2011). It has been demonstrated that the electrical activity of two electrically coupled b-cells can exhibit different forms of synchronous activities, both in vivo (Valdeolmillos et al 1996) and in vitro (Eddlestone et al 1984).…”

Section: Introductionmentioning

confidence: 99%

Bursting synchronization dynamics of pancreatic β-cells with electrical and chemical coupling

Meng

Wang

2012

Cogn Neurodyn

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Based on bifurcation analysis, the synchronization behaviors of two identical pancreatic b-cells connected by electrical and chemical coupling are investigated, respectively. Various firing patterns are produced in coupled cells when a single cell exhibits tonic spiking or square-wave bursting individually, irrespectively of what the cells are connected by electrical or chemical coupling. On the one hand, cells can burst synchronously for both weak electrical and chemical coupling when an isolated cell exhibits tonic spiking itself. In particular, for electrically coupled cells, under the variation of the coupling strength there exist complex transition processes of synchronous firing patterns such as ''fold/limit cycle'' type of bursting, then anti-phase continuous spiking, followed by the ''fold/torus'' type of bursting, and finally in-phase tonic spiking. On the other hand, it is shown that when the individual cell exhibits square-wave bursting, suitable coupling strength can make the electrically coupled system generate ''fold/Hopf'' bursting via ''fold/fold'' hysteresis loop; whereas, the chemically coupled cells generate ''fold/ subHopf'' bursting. Especially, chemically coupled bursters can exhibit inverse period-adding bursting sequence. Fast-slow dynamics analysis is applied to explore the generation mechanism of these bursting oscillations. The above analysis of bursting types and the transition may provide us with better insight into understanding the role of coupling in the dynamic behaviors of pancreatic b-cells.

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Burst synchronization transitions in a neuronal network of subnetworks

Cited by 172 publications

References 60 publications

Dynamics of in-phase and anti-phase bursting in the coupled pre-Bötzinger complex cells

Dynamics of in-phase and anti-phase bursting in the coupled pre-Bötzinger complex cells

Autaptic Modulation of Electrical Activity in a Network of Neuron-Coupled Astrocyte

Bursting synchronization dynamics of pancreatic β-cells with electrical and chemical coupling

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