Effective dynamics of twisted and curved scroll waves using virtual filaments

Dierckx, Hans; Verschelde, Henri

doi:10.1103/physreve.88.062907

Cited by 11 publications

(17 citation statements)

References 70 publications

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“…Recently, Dierckx et al [326] have calculated higher orders in the perturbation theory in generic models of excitable media.…”

Section: Negative Line Tensionmentioning

confidence: 99%

“…Defining p(σ, t), the unit vector pointing orthogonally from the center filament to the line of instantaneous scroll wave tips, the scroll wave twist can be defined as τ = (p × ∂ s p) · T. Then, a phenomenological extension of Eqs. (78)- (80) for a twisted scroll wave was developed in [160] (a more rigorous derivation can be found in [326]), giving…”

Section: Equations For Filament Motionmentioning

confidence: 99%

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Nonlinear physics of electrical wave propagation in the heart: a review

2016

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Abstract. The beating of the heart is a synchronized contraction of muscle cells (myocytes) that are triggered by a periodic sequence of electrical waves (action potentials) originating in the sino-atrial node and propagating over the atria and the ventricles. Cardiac arrhythmias like atrial and ventricular fibrillation (AF,VF) or ventricular tachycardia (VT) are caused by disruptions and instabilities of these electrical excitations, that lead to the emergence of rotating waves (VT) and turbulent wave patterns (AF,VF). Numerous simulation and experimental studies during the last 20 years have addressed these topics. In this review we focus on the nonlinear dynamics of wave propagation in the heart with an emphasis on the theory of pulses, spirals and scroll waves and their instabilities in excitable media and their application to cardiac modeling. After an introduction into electrophysiological models for action potential propagation, the modeling and analysis of spatiotemporal alternans, spiral and scroll meandering, spiral breakup and scroll wave instabilities like negative line tension and sproing are reviewed in depth and discussed with emphasis on their impact in cardiac arrhythmias.

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“…Recently, Dierckx et al [326] have calculated higher orders in the perturbation theory in generic models of excitable media.…”

Section: Negative Line Tensionmentioning

confidence: 99%

Section: Equations For Filament Motionmentioning

confidence: 99%

Nonlinear physics of electrical wave propagation in the heart: a review

2016

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“…Overlap integrals of spiral wave RFs thus appear in the equations of motion for three-dimensional scroll wave filaments, [13][14][15][16] or in the theory of 2D spiral waves drifting due to a constant external field, 17 surface curvature, 18 or mechano-electrical feedback. 19 In one spatial dimension, the translational RF of the wave front determines the velocitycurvature relation 20,21 and the shape of the RF itself can be used to shape reaction-diffusion patterns.…”

Section: DXmentioning

confidence: 99%

Measurement and structure of spiral wave response functions

Dierckx¹,

Verschelde²,

Panfilov³

2017

Chaos: An Interdisciplinary Journal of Nonlinear Science

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The rotating spiral waves that emerge in diverse natural and man-made systems typically exhibit a particle-like behaviour since their adjoint critical eigenmodes (response functions) are often seen to be localised around the spiral core. We present a simple method to numerically compute response functions for circular-core and meandering spirals by recording their drift response to many elementary perturbations. Although our method is computationally more expensive than solving the adjoint system, our technique is fully parallellisable, does not suffer from memory limitations and can be applied to experiments. For a cardiac tissue model with the linear spiral core, we find that the response functions are localised near the turning points of the trajectory.

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“…A higher-order asymptotic equation for filament motion was obtained by Dierckx and Verschelde [2013]. Unlike the leading order (10), it is coupled to t = 75 t = 150 t = 300 Wavefronts are cut out by clipping planes halfway through the volume, to reveal the filaments [Dierckx et al, 2012].…”

Section: Perturbative Dynamics Of Scrolls and Tension Of Filamentsmentioning

confidence: 99%

“…The vector-function R(s, t) in (14) is the "virtual filament" which has to be defined more precisely than (9), and the coefficients are defined as integrals involving spiral wave response functions, similar to but more complicated than (11); see [Dierckx and Verschelde, 2013] for detail.…”

Section: Perturbative Dynamics Of Scrolls and Tension Of Filamentsmentioning

confidence: 99%