Patterns of Synchrony in Complex Networks of Adaptively Coupled Oscillators

Berner, Rico

doi:10.1007/978-3-030-74938-5

Cited by 15 publications

(15 citation statements)

References 224 publications

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“…Synchronization is an important feature of the dynamics in networks of coupled nonlinear oscillators Pikovsky et al (2001), Strogatz (2001), Albert and Barabási (2002), Newman (2003), Boccaletti et al (2018), Berner (2021). Various synchronization patterns are known such as cluster synchronization where the network splits into groups of synchronous elements Dahms et al (2012), or partial synchronization patterns such as chimera states where the system splits into coexisting domains of coherent (synchronized) and incoherent (desynchronized) states Kuramoto and Battogtokh (2002), Abrams and Strogatz (2004), Panaggio and Abrams (2015), Sawicki (2019), Schöll (2020), Schöll et al (2020).…”

Section: Introductionmentioning

confidence: 99%

Modeling Tumor Disease and Sepsis by Networks of Adaptively Coupled Phase Oscillators

Sawicki

Berner

Löser³

et al. 2022

Front. Netw. Physiol.

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In this study, we provide a dynamical systems perspective to the modelling of pathological states induced by tumors or infection. A unified disease model is established using the innate immune system as the reference point. We propose a two-layer network model for carcinogenesis and sepsis based upon the interaction of parenchymal cells and immune cells via cytokines, and the co-evolutionary dynamics of parenchymal, immune cells, and cytokines. Our aim is to show that the complex cellular cooperation between parenchyma and stroma (immune layer) in the physiological and pathological case can be qualitatively and functionally described by a simple paradigmatic model of phase oscillators. By this, we explain carcinogenesis, tumor progression, and sepsis by destabilization of the healthy homeostatic state (frequency synchronized), and emergence of a pathological state (desynchronized or multifrequency cluster). The coupled dynamics of parenchymal cells (metabolism) and nonspecific immune cells (reaction of innate immune system) are represented by nodes of a duplex layer. The cytokine interaction is modeled by adaptive coupling weights between the nodes representing the immune cells (with fast adaptation time scale) and the parenchymal cells (slow adaptation time scale) and between the pairs of parenchymal and immune cells in the duplex network (fixed bidirectional coupling). Thereby, carcinogenesis, organ dysfunction in sepsis, and recurrence risk can be described in a correct functional context.

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Section: Introductionmentioning

confidence: 99%

Modeling Tumor Disease and Sepsis by Networks of Adaptively Coupled Phase Oscillators

Sawicki

Berner

Löser³

et al. 2022

Front. Netw. Physiol.

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“…Of particular interest are adaptive networks in which connectivity changes are related to intrinsic nodal dynamics (Gross and Blasius, 2008;Berner, 2021). For example, these types of networks can model synaptic neuronal plasticity (Meisel and Gross, 2009;Markram et al, 2011), chemical (Jain and Krishna, 2001;Kuehn, 2019), epidemic (Gross et al, 2006), biological, and social systems (Horstmeyer and Kuehn, 2020).…”

Section: Introductionmentioning

confidence: 99%

Collective Activity Bursting in a Population of Excitable Units Adaptively Coupled to a Pool of Resources

Franović

Eydam

Yanchuk

et al. 2022

Front. Netw. Physiol.

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We study the collective dynamics in a population of excitable units (neurons) adaptively interacting with a pool of resources. The resource pool is influenced by the average activity of the population, whereas the feedback from the resources to the population is comprised of components acting homogeneously or inhomogeneously on individual units of the population. Moreover, the resource pool dynamics is assumed to be slow and has an oscillatory degree of freedom. We show that the feedback loop between the population and the resources can give rise to collective activity bursting in the population. To explain the mechanisms behind this emergent phenomenon, we combine the Ott-Antonsen reduction for the collective dynamics of the population and singular perturbation theory to obtain a reduced system describing the interaction between the population mean field and the resources.

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“…Other relevant applications are communication, supply, and transportation networks, for instance power grids, subway networks, or airtraffic networks 54 . Moreover, multilayer networks are also known to generate and stabilize diverse partial synchronization patterns in adaptive networks 55,56 , where the connectivity changes in time 57 .…”

Section: Introductionmentioning

confidence: 99%

Synchronization scenarios in three-layer networks with a hub

Sawicki,

Koulen,

Schöll

2021

Preprint

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Patterns of Synchrony in Complex Networks of Adaptively Coupled Oscillators

Cited by 15 publications

References 224 publications

Modeling Tumor Disease and Sepsis by Networks of Adaptively Coupled Phase Oscillators

Modeling Tumor Disease and Sepsis by Networks of Adaptively Coupled Phase Oscillators

Collective Activity Bursting in a Population of Excitable Units Adaptively Coupled to a Pool of Resources

Synchronization scenarios in three-layer networks with a hub

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