Control of electrical alternans in simulations of paced myocardium using extended time-delay autosynchronization

Berger, Carolyn; Cain, John W.; Socolar, Joshua E. S.; Gauthier, Daniel J.

doi:10.1103/physreve.76.041917

Cited by 13 publications

(9 citation statements)

References 40 publications

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“…where A max = 392 ms, β = 525 ms, and τ = 40 ms. For this mapping, the bifurcation to alternans occurs when B ≈ 455 ms; for a bifurcation diagram of (9) and (10), see [18]. While one-dimensional restitution models of the form (9) may be appropriate in some settings, A n+1 is influenced not only by A n , but also by a variety of other factors.…”

Section: Example: Two Models Of Cardiac Restitutionmentioning

confidence: 99%

Restricted feedback control in discrete-time dynamical systems with memory

2014

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When an equilibrium state of a physical or biological system suffers a loss of stability (e.g., via a bifurcation), it may be both possible and desirable to stabilize the equilibrium via closed-loop feedback control. Significant effort has been devoted towards using such control to prevent oscillatory or chaotic behavior in dynamical systems, both continuous-time and discrete-time. Regarding control in discrete-time systems, most prior attempts to stabilize unstable equilibria require that the system be perturbed once during each time step. However, there are examples of systems for which this is neither feasible nor possible. In this paper, we analyze a restricted feedback control method for discrete-time systems (restricted in the sense that the controller's perturbations may be applied only in every other time step). We apply our theoretical analysis to a specific example from cardiac electrophysiology in which this sort of restricted feedback control is especially relevant. The example is a useful test case for the theory, and one for which an experimental setup is rather straightforward.

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Section: Example: Two Models Of Cardiac Restitutionmentioning

confidence: 99%

Restricted feedback control in discrete-time dynamical systems with memory

2014

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“…Besides the earlier proposed methods for alternans suppression: the proportional feedback control [6,7] and adaptive scheme [8][9][10], a new control scheme, the T+T-feedback control [11][12][13][14] was proposed recently. The basic pacing period T in this method is designed to change between two values, T +  and T - (where  is a predetermined control parameter and is much less than T), repeatedly until the alternans is suppressed.…”

Section: Introductionmentioning

confidence: 99%

“…It may lead to life-threatening cardiac arrhythmias [3,4], such as ventricular tachycardia and ventricular fibrillation, or sudden cardiac death [4,5] if it is left without any further medical treatment or intervention. Therefore, searching for an effective alternans control method is crucial.Besides the earlier proposed methods for alternans suppression: the proportional feedback control [6,7] and adaptive scheme [8][9][10], a new control scheme, the T+T-feedback control [11][12][13][14] was proposed recently. The basic pacing period T in this method is designed to change between two values, T +  and T - (where  is a predetermined control parameter and is much less than T), repeatedly until the alternans is suppressed.…”

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confidence: 99%

Effect of Extracellular Calcium Concentration on Controlling Cardiac Alternans

Liang

Lai

2017

Computing in Cardiology Conference (CinC)

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IntroductionCardiac arrhythmia is a condition where heartbeats are abnormal. Every year, millions of people worldwide experience arrhythmias and many of them can return to their normal lives if the arrhythmias are treated at early stages and properly. However, many arrhythmias are dangerous and may lead to sudden cardiac death.Cardiac alternans [1,2], which can be induced by fast pacing, is the condition of having alternate-beat oscillation in the electrical activity (the action potential durations, APDs, oscillate in a long-short-long-short pattern) or alternating strong and weak beats in a heart under a constant pacing. It may lead to life-threatening cardiac arrhythmias [3,4], such as ventricular tachycardia and ventricular fibrillation, or sudden cardiac death [4,5] if it is left without any further medical treatment or intervention. Therefore, searching for an effective alternans control method is crucial.Besides the earlier proposed methods for alternans suppression: the proportional feedback control [6,7] and adaptive scheme [8][9][10], a new control scheme, the T+T-feedback control [11][12][13][14] was proposed recently. The basic pacing period T in this method is designed to change between two values, T +  and T - (where  is a predetermined control parameter and is much less than T), repeatedly until the alternans is suppressed. Experiments [11,13] and theoretical [11][12][13][14] studies have been carried out and the results showed that the T+T-control method can suppress alternans effectively. However, when the pacing rate continues to increase, the amplitude of the alternans also increases and becomes more difficult to be controlled. Thus, it is necessary to look into how the T+T-control method can be improved to suppress alternans induced by rapid pacing.During cardiac alternans, the intracellular calcium concentration ([Ca] [18,19] showing that lowering extracellular calcium concentration ([Ca]o) can suppress alternans, it is interesting to examine the combination of T+T-control method and low [Ca]o as a possible more effective alternans control method. In this study, we investigated the time needed to suppress cardiac alternans using the T+T-control method with lower [Ca]o during the control. The details of the control scheme and numerical calculation are given in the next section, followed by the results. In the last section, we discuss our significant findings and the clinical implications. MethodsThe Hund-Rudy dynamic (HRd) model of canine ventricular action potential [2,20], which is one of the typical mathematical models used to study cardiac alternans, was used in this study to simulate the alternans of a single cell. The HRd model includes the ionic-currents, pumps, exchangers, dynamic concentration change of ions, and calcium cycling. The rate of change of the membrane potential (V) is described by the following equation:

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“…2-7,9-12,19 In most of these studies, alternans was suppressed using appropriately timed electrical stimuli, delivered through electrodes embedded in simulated or real tissue. Other researchers have suggested using alternate methods, such as the application of mechanical stimuli 16 or drug delivery, 17 for reversing unwanted AP patterns.…”

Section: Introductionmentioning

confidence: 99%

Applications of Control Theory to the Dynamics and Propagation of Cardiac Action Potentials

2010

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Sudden cardiac arrest is a widespread cause of death in the industrialized world. Most cases of sudden cardiac arrest are due to ventricular fibrillation (VF), a lethal cardiac arrhythmia. Electrophysiological abnormalities such as alternans (a beat-to-beat alternation in action potential duration) and conduction block have been suspected to contribute to the onset of VF. This study focuses on the use of control-systems techniques to analyze and design methods for suppressing these precursor factors. Control-systems tools, specifically controllability analysis and Lyapunov stability methods, were applied to a two-variable Karma model of the action-potential (AP) dynamics of a single cell, to analyze the effectiveness of strategies for suppressing AP abnormalities. State-feedback-integral (SFI) control was then applied to a Purkinje fiber simulated with the Karma model, where only one stimulating electrode was used to affect the system. SFI control converted both discordant alternans and 2:1 conduction block back toward more normal patterns, over a wider range of fiber lengths and pacing intervals compared with a Pyragas-type chaos controller. The advantages conferred by using feedback from multiple locations in the fiber, and using integral (i.e., memory) terms in the controller, are discussed.

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Control of electrical alternans in simulations of paced myocardium using extended time-delay autosynchronization

Cited by 13 publications

References 40 publications

Restricted feedback control in discrete-time dynamical systems with memory

Restricted feedback control in discrete-time dynamical systems with memory

Effect of Extracellular Calcium Concentration on Controlling Cardiac Alternans

Applications of Control Theory to the Dynamics and Propagation of Cardiac Action Potentials

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