Elimination of spiral waves in excitable media by magnetic induction

Rostami, Zahra; Jafari, Sajad; Perc, Matjaž; Slavinec, Mitja

doi:10.1007/s11071-018-4385-9

Cited by 46 publications

(2 citation statements)

References 48 publications

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“…Fig. 9: Network snapshots considering temperature affected potassium ion channels in TDML model without electromagnetic field coupling Many literatures have discussed the effect of magnetic coupling on spiral waves [20,21,[28][29][30] and some have shown that the electromagnetic flux coupling can effectively suppress the spiral waves [33]. Hence, we consider the TDML model with electromagnetic coupling and consider them as individual node in the network (5).…”

Section: Case-a: Temperature Sensitive Calcium Ion Channelsmentioning

confidence: 99%

Effect of temperature sensitive ion channels on the single and multilayer network behavior of an excitable media with electromagnetic induction

Karthikeyan¹,

Moroz

Rajagopal

et al. 2021

Chaos, Solitons & Fractals

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Section: Case-a: Temperature Sensitive Calcium Ion Channelsmentioning

confidence: 99%

Effect of temperature sensitive ion channels on the single and multilayer network behavior of an excitable media with electromagnetic induction

Karthikeyan¹,

Moroz

Rajagopal

et al. 2021

Chaos, Solitons & Fractals

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“…Furthermore, this spontaneous electromagnetic induction can induce abundant chaotic dynamics in a previously steady-state neural network; this phenomenon has been experimentally proven with an equivalent electric circuit model of the neural network in PSpice 53 . More importantly, spontaneous electromagnetic induction in neurons provides a reasonable and effective path to study the effect of external electromagnetic fields on neural system functions 48,55–58 . For example, the electromagnetic radiation can induce diverse synchronizations 55,59 , stochastic resonance 60 , rhythm disorder 59 and mode transitions of electrical activities 56 in the neuronal network; in particular, an optimal electromagnetic radiation intensity can induce the occurrence of stochastic resonance and a maximal neuronal response to weak signals 55 .…”

Section: Introductionmentioning

confidence: 99%

Spontaneous electromagnetic induction promotes the formation of economical neuronal network structure via self-organization process

Wang

Fan

2019

Sci Rep

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Developed through evolution, brain neural system self-organizes into an economical and dynamic network structure with the modulation of repetitive neuronal firing activities through synaptic plasticity. These highly variable electric activities inevitably produce a spontaneous magnetic field, which also significantly modulates the dynamic neuronal behaviors in the brain. However, how this spontaneous electromagnetic induction affects the self-organization process and what is its role in the formation of an economical neuronal network still have not been reported. Here, we investigate the effects of spontaneous electromagnetic induction on the self-organization process and the topological properties of the self-organized neuronal network. We first find that spontaneous electromagnetic induction slows down the self-organization process of the neuronal network by decreasing the neuronal excitability. In addition, spontaneous electromagnetic induction can result in a more homogeneous directed-weighted network structure with lower causal relationship and less modularity which supports weaker neuronal synchronization. Furthermore, we show that spontaneous electromagnetic induction can reconfigure synaptic connections to optimize the economical connectivity pattern of self-organized neuronal networks, endowing it with enhanced local and global efficiency from the perspective of graph theory. Our results reveal the critical role of spontaneous electromagnetic induction in the formation of an economical self-organized neuronal network and are also helpful for understanding the evolution of the brain neural system.

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Localized modulated wave solution of diffusive FitzHugh–Nagumo cardiac networks under magnetic flow effect

et al. 2018

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Elimination of spiral waves in excitable media by magnetic induction

Cited by 46 publications

References 48 publications

Effect of temperature sensitive ion channels on the single and multilayer network behavior of an excitable media with electromagnetic induction

Effect of temperature sensitive ion channels on the single and multilayer network behavior of an excitable media with electromagnetic induction

Spontaneous electromagnetic induction promotes the formation of economical neuronal network structure via self-organization process

Localized modulated wave solution of diffusive FitzHugh–Nagumo cardiac networks under magnetic flow effect

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