Spiral waves of excitation underlie reentrant activity in isolated cardiac muscle.

Pertsov, Arkady M.; Davidenko, Jorge M.; Salomonsz, Remy; Baxter, William T.; Jalife, José

doi:10.1161/01.res.72.3.631

Cited by 560 publications

(366 citation statements)

References 53 publications

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“…The anatomic heterogeneities, which are naturally present, also facilitate conduction blocks and wavebreaks through the source-sink mismatches. 13 For example, epicardial coronary arteries, 14 papillary muscles, 15 transmural sites with abrupt fiber orientation changes, 16 and increased fibrosis resulting from cardiomyopathy 17 can all serve as sites of wavebreaks. With the more recent appreciation that dynamic factors related to electrical restitution also play a key role in facilitating wavebreak, an updated version of the Multiple Wavelet Hypothesis emphasizes that the synergy between dynamic factors and preexisting tissue heterogeneities are the fundamental cause of wavebreaks perpetuating VF.…”

Section: Multiple Wavelet Hypothesismentioning

confidence: 99%

A Tale of Two Fibrillations

et al. 2003

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Section: Multiple Wavelet Hypothesismentioning

confidence: 99%

A Tale of Two Fibrillations

et al. 2003

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“…The remodeled tissue could generate focal ectopic activities that could propagate and form re-entry circuits. The atrial regions hosting such behaviors are important in the initiation and perpetuation of the arrhythmia [5,6]. Dominant frequency (DF) measured from atrial electrograms (AEGs) is believed to represent their main activation rate [7,8].…”

Section: Introductionmentioning

confidence: 99%

An interactive platform to guide catheter ablation in human persistent atrial fibrillation using dominant frequency, organization and phase mapping

Salinet

Almeida

et al. 2017

Computer Methods and Programs in Biomedicine

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“…+ r Spirals are generic structures in extended nonequilibrium systems. They are characteristic of many reactiondiffusion systems [1], the most paradigmatic experimental example being the Belousov-Zhabotinsky (BZ) reaction [2], and they have been observed in systems as complex as the heart muscle associated to cardiac fibrillation [3,4]. Spiral patterns appear also as elementary solutions of the complex Ginzburg-Landau (CGL) equation [5].…”

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confidence: 99%

Brownian Motion of Spiral Waves Driven by Spatiotemporal Structured Noise

et al. 2000

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Spiral chemical waves subjected to a spatiotemporal random excitability are experimentally and numerically investigated in relation to the light-sensitive Belousov-Zhabotinsky reaction. Brownian motion is identified and characterized by an effective diffusion coefficient which shows a rather complex dependence on the time and length scales of the noise relative to those of the spiral. A kinematically based model is proposed whose results are in good qualitative agreement with experiments and numerics. PACS numbers: 82.40.Bj, 05.45.Jn, 47.54. + r Spirals are generic structures in extended nonequilibrium systems. They are characteristic of many reactiondiffusion systems [1], the most paradigmatic experimental example being the Belousov-Zhabotinsky (BZ) reaction [2], and they have been observed in systems as complex as the heart muscle associated to cardiac fibrillation [3,4]. Spiral patterns appear also as elementary solutions of the complex Ginzburg-Landau (CGL) equation [5].Beyond the standard description of spiral waves, their response to spatial and/or temporal forcing has been largely analyzed. Temporal resonance [6], drift of vortices due to parameter gradients [7,8] or external fields [9], and anchoring on localized defects [10] are among the most studied effects.On the other hand, the influence of random heterogeneities on extended excitable systems has recently attracted much attention. Noise as an initiator of new spatial structures [11][12][13], or sustaining wave propagation in subexcitable media [14][15][16], is a subject of much theoretical and experimental interest. Complementarily, the role of superimposed disorder on preexisting spatiotemporal patterns has been examined, in relation to propagating pulses [17], to the dynamics of CGL spirals [18] and 3D structures [19].In this paper, we study the effect of a spatiotemporal structured noise on the motion of a spiral wave for the photosensitive BZ reaction. In the absence of randomness, the spiral tip rotates quasirigidly around its core, with no net translational mobility. When the noise is switched on, Brownian diffusion of the spiral is observed, characterized by a nonmonotonous dependence on the parameters of the noise. These observations are confirmed numerically using a two-variable Oregonator model. The analysis is completed by proposing a simple theoretical model based on a kinematic approach [20], capturing the basic features observed in experiments.Experiments were carried out in a Petri dish of 9 cm diameter. The catalyst, ruthenium bipyridil, is immobilized in a thin, 1 mm thick, film of silica gel, prepared as in [21].A solution of catalyst-free BZ reaction (initial concentrations 0.18M KBr, 0.33M malonic acid, 0.39M NaBrO 3 , and 0.50M H 2 SO 4 ) was poured onto the gel. The temperature was kept constant at 25 6 1 ± C. Spatiotemporal noise is introduced by projecting on to the Petri dish the desired patterned illumination, controlling the excitability of the system, by means of a video projector (SONY CPJ-D500). Experiments were capt...

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Spiral waves of excitation underlie reentrant activity in isolated cardiac muscle.

Cited by 560 publications

References 53 publications

A Tale of Two Fibrillations

A Tale of Two Fibrillations

An interactive platform to guide catheter ablation in human persistent atrial fibrillation using dominant frequency, organization and phase mapping

Brownian Motion of Spiral Waves Driven by Spatiotemporal Structured Noise

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