Controlling Spatiotemporal Chaos and Spiral Turbulence in Excitable Media

Sinha, Sitabhra; Sridhar, S.

doi:10.1002/9783527622313.ch32

Cited by 5 publications

(5 citation statements)

References 40 publications

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“…For example, rotating vortices in cardiac tissue that can lead to spiral chaos underlie many arrhythmias, i.e., life-threatening disturbances in the natural rhythm of the heart [14,15]. Thus, controlling irregular activity in excitable media is not only a problem of fundamental interest in the physics of nonlinear dynamical systems but also has potential clinical significance [16][17][18][19]. Existing methods of spatiotemporal chaos control in excitable systems are almost exclusively dependent on using suprathreshold signals, either through a local high-frequency source [20,21] or using a spatially extended array [22][23][24].…”

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confidence: 99%

Response to sub-threshold stimulus is enhanced by spatially heterogeneous activity

Sridhar

Sinha

2010

EPL

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Sub-threshold stimuli cannot initiate excitations in active media, but surprisingly as we show in this paper, they can alter the time-evolution of spatially heterogeneous activity by modifying the recovery dynamics. This results in significant reduction of waveback velocity which may lead to spatial coherence, terminating all activity in the medium including spatiotemporal chaos. We analytically derive model-independent conditions for which such behavior can be observed.

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confidence: 99%

Response to sub-threshold stimulus is enhanced by spatially heterogeneous activity

Sridhar

Sinha

2010

EPL

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“…So far, various low-amplitude suppression algorithms have been developed to eliminate spiral waves in monodomain mathematical models of cardiac tissue; in these algorithms the control pulses are applied in several ways. These include the following: (a) periodic stimulation at a point (Zhang et al, 2003 ; Yuan et al, 2005 ); (b) a line stimulus that must be applied to one of the boundaries (Tang et al, 2008 ; Miguel et al, 2009 ); (c) an array of low-voltage control pulses, which must be swept over the simulation domain (Sinha and Sridhar, 2007 ; Sridhar and Sinha, 2008 ); or (d) the mesh-based, low-amplitude suppression scheme we describe (Sinha et al, 2001 ; Pandit et al, 2002 ). We have provided an overview of such low-amplitude suppression schemes, in the absence of PD, in earlier studies (Shajahan et al, 2009 ; Nayak, 2013 ); the most successful of these is based on a mesh-based suppression algorithm; this suppression scheme (Shajahan et al, 2009 ; Majumder et al, 2011a ; Nayak et al, 2013 ) can suppress spiral waves of electrical activation even in the presence of conduction, ionic, and fibroblast heterogeneities (Shajahan et al, 2009 ; Majumder et al, 2011a ; Nayak et al, 2013 ).…”

Section: Resultsmentioning

confidence: 99%

Spiral-wave dynamics in ionically realistic mathematical models for human ventricular tissue: the effects of periodic deformation

Nayak

Pandit

2014

Front. Physiol.

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We carry out an extensive numerical study of the dynamics of spiral waves of electrical activation, in the presence of periodic deformation (PD) in two-dimensional simulation domains, in the biophysically realistic mathematical models of human ventricular tissue due to (a) ten-Tusscher and Panfilov (the TP06 model) and (b) ten-Tusscher, Noble, Noble, and Panfilov (the TNNP04 model). We first consider simulations in cable-type domains, in which we calculate the conduction velocity θ and the wavelength λ of a plane wave; we show that PD leads to a periodic, spatial modulation of θ and a temporally periodic modulation of λ; both these modulations depend on the amplitude and frequency of the PD. We then examine three types of initial conditions for both TP06 and TNNP04 models and show that the imposition of PD leads to a rich variety of spatiotemporal patterns in the transmembrane potential including states with a single rotating spiral (RS) wave, a spiral-turbulence (ST) state with a single meandering spiral, an ST state with multiple broken spirals, and a state SA in which all spirals are absorbed at the boundaries of our simulation domain. We find, for both TP06 and TNNP04 models, that spiral-wave dynamics depends sensitively on the amplitude and frequency of PD and the initial condition. We examine how these different types of spiral-wave states can be eliminated in the presence of PD by the application of low-amplitude pulses by square- and rectangular-mesh suppression techniques. We suggest specific experiments that can test the results of our simulations.

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“…The idea being that if ventricular fibrillation is deterministic chaos, then it should be terminable using stimuli smaller, less painful and/or damaging, than large defibrillation shocks. Unfortunately, while chaos-control efficacy has been demonstrated in experimental work and computer simulations (141, 142), it has not been successful in terminating fibrillation in the clinic. New strategies for unpinning and suppressing spiral and scroll waves based on theoretical and simulation work are under development (e.g., (143, 144), and some show promise in experiments (145, 146).…”

Section: Conclusion: Therapy Translation and Future Perspectivesmentioning

confidence: 99%

Nonlinear Dynamics in Cardiology

Krogh‐Madsen

Christini

2012

Annu. Rev. Biomed. Eng.

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The dynamics of many cardiac arrhythmias, as well as the nature of transitions between different heart rhythms, have long been considered evidence of nonlinear phenomena playing a direct role in cardiac arrhythmogenesis. In most types of cardiac disease, the pathology develops slowly and gradually, often over many years. In contrast, arrhythmias often occur suddenly. In nonlinear systems, sudden changes in qualitative dynamics can, counter-intuitively, result from a gradual change in a system parameter –this is known as a bifurcation. Here, we review how nonlinearities in cardiac electrophysiology influence normal and abnormal rhythms and how bifurcations change the dynamics. In particular, we focus on the many recent developments in computational modeling at the cellular level focused on intracellular calcium dynamics. We discuss two areas where recent experimental and modeling work have suggested the importance of nonlinearities in calcium dynamics: repolarization alternans and pacemaker cell automaticity.

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Controlling Spatiotemporal Chaos and Spiral Turbulence in Excitable Media

Cited by 5 publications

References 40 publications

Response to sub-threshold stimulus is enhanced by spatially heterogeneous activity

Response to sub-threshold stimulus is enhanced by spatially heterogeneous activity

Spiral-wave dynamics in ionically realistic mathematical models for human ventricular tissue: the effects of periodic deformation

Nonlinear Dynamics in Cardiology

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