Alternans and higher-order rhythms in an ionic model of a sheet of ischemic ventricular muscle

Arce, Humberto; Xu, Aoxiang; González, Hortensia; Guevara, Michael R.

doi:10.1063/1.166508

Cited by 30 publications

(24 citation statements)

References 131 publications

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“…The intracellular ion concentration handling in second-generation models can be a source of instabilities (2,12 dynamics but were mainly interested in the overall properties of I Ca and its influence on the AP shape and restitution properties of cardiac tissue. Moreover, in the PB model, the calcium subsystem is represented by a model that mimics Ca 2ϩ -induced Ca 2ϩ release as an all-or-none event and reproduces Ca 2ϩ transients with realistic amplitudes but is phenomenological in construction and is not sufficient to accommodate predictions of intracellular Ca 2ϩ dynamics under more complex experimental conditions.…”

Section: Reduction Of the Pb Modelmentioning

confidence: 99%

“…Second, the PB model is a "second-generation model" in which, besides membrane potential and gating variables, ion concentrations vary in time. Secondgeneration models made up of ordinary differential equations describing the time dependence of membrane potential, gating variables, and ion concentrations, are inherently unstable, showing complications involving long-term drifts of ion concentrations and degeneracy of equilibria, as recently emphasized by both Arce et al (2) and Endresen and Skarland (12).…”

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confidence: 99%

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A computationally efficient electrophysiological model of human ventricular cells

Bernus

Wilders

Zemlin

et al. 2002

American Journal of Physiology-Heart and Circulatory Physiology

130

125

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-Recent experimental and theoretical results have stressed the importance of modeling studies of reentrant arrhythmias in cardiac tissue and at the whole heart level. We introduce a sixvariable model obtained by a reformulation of the PriebeBeuckelmann model of a single human ventricular cell. The reformulated model is 4.9 times faster for numerical computations and it is more stable than the original model. It retains the action potential shape at various frequencies, restitution of action potential duration, and restitution of conduction velocity. We were able to reproduce the main properties of epicardial, endocardial, and M cells by modifying selected ionic currents. We performed a simulation study of spiral wave behavior in a two-dimensional sheet of human ventricular tissue and showed that spiral waves have a frequency of 3.3 Hz and a linear core of ϳ50-mm diameter that rotates with an average frequency of 0.62 rad/s. Simulation results agreed with experimental data. In conclusion, the proposed model is suitable for efficient and accurate studies of reentrant phenomena in human ventricular tissue. action potential; computer simulation; mathematical model; reentrant arrhythmia; spiral wave THE HISTORY of modeling biological excitable media such as nerve and heart tissue started 50 years ago with the Hodgkin-Huxley model of the giant squid axon (19). The first model of cardiac tissue (Purkinje fibers) was proposed by Noble in 1962 (30) and consisted of four variables. During the following decades, the experimental techniques for studying the properties of the cell membrane were improved continuously, leading to new cardiac tissue models of increasing accuracy, e.g., the phase- The Priebe-Beuckelmann (PB) model is based on the phase-2 LR model. However, five major ionic currents, including the fast (I Kr ) and slow (I Ks ) components of the delayed rectifier K ϩ current, the L-type Ca 2ϩ current (I Ca ), the transient outward K ϩ current (I to ), and the inward rectifier K ϩ current (I K1 ), are based on experimental data obtained on human myocytes. In addition, parameters of the intracellular Ca 2ϩ concentration ([Ca 2ϩ ] i ) handling were changed in such a way that simulated transients are comparable to observed experimental data on human myocytes (4). The remaining currents have been adjusted from the LR model, with their amplitude scaled to fit human cell data.Priebe and Beuckelmann developed their model to compare the electrophysiological properties of failing and nonfailing ventricular myocytes. It can be used for accurate simulations of the ionic currents and concentrations in a single cell during electrical activity. Our objective, however, is to simulate reentrant sources of arrhythmias in two (2-D) and three dimensions (3-D), which are believed to underlie most ventricular tachycardias and ventricular fibrillation (18,21,43). Although the PB model is based on experimental measurements in human heart tissue, we refrained from using it for the study of reentrant arrhythmias for several reasons. F...

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Section: Reduction Of the Pb Modelmentioning

confidence: 99%

mentioning

confidence: 99%

A computationally efficient electrophysiological model of human ventricular cells

Bernus

Wilders

Zemlin

et al. 2002

American Journal of Physiology-Heart and Circulatory Physiology

130

125

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show abstract

“…The latter, spatial heterogeneity of APD, has received considerable attention in recent years because APD differences can cause dispersion of repolarization, creating a situation in which a premature stimulus can cause unidirectional block and thus initiate reentry (1). In the diseased heart, these APD differences can be greatly enhanced, leading to marked heterogeneity of repolarization that can cause conduction block in the absence of premature stimulation (3,33).…”

Section: Introductionmentioning

confidence: 99%

Spatial heterogeneity of the restitution portrait in rabbit epicardium

Pitruzzello¹,

Krassowska²,

Idriss³

2007

American Journal of Physiology-Heart and Circulatory Physiology

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Spatial heterogeneity of repolarization can provide a substrate for reentry to occur in myocardium. This heterogeneity may result from spatial differences in APD restitution. The restitution portrait (RP) measures many aspects of rate-dependent restitution: the dynamic restitution curve (RC), S1-S2 RC, and short-term memory response. We used the RP to characterize epicardial patterns of spatial heterogeneity of restitution that were repeatable across animals. NZW rabbit ventricles were paced from either the epicardial apex, mid-ventricle, or base, and optical action potentials were recorded from the same three regions. A perturbed downsweep pacing protocol was applied that measured the RP over a range of cycle lengths from 1000-140 ms. The time constant of short-term memory measured close to the stimulus was dependent on location. In the mid-ventricle the mean time constant was 19.1±1.1 sec, but it was 39% longer at the apex (p<0.01) and 23% longer at the base (p=0.03). The S1-S2 RC slope was dependent on pacing site (p=0.015), with steeper slope when pacing from the apex than from the base. There were no significant repeatable spatial patterns in steady-state APD at all cycle lengths or in dynamic RC slope. These results indicate that transient patterns of epicardial heterogeneity of APD may occur following a change in pacing rate. Thus, it may affect cardiac electrical stability at the onset of a tachycardia or during a series of ectopic beats. Differences in restitution with respect to pacing site suggest that vulnerability may be affected by the location of reentry or ectopic foci.

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“…Heterogeneity has been studied methodically in computational models using regions with prolonged refractoriness (19), elevated extracellular K ϩ concentration (1,27), cell-cell decoupling (6), or simulated ischemia (7,12,28). Common among these situations is the localized slowing of conduction, which facilitates the formation of conduction block that is a prerequisite for reentry.…”

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Region of slowed conduction acts as core for spiral wave reentry in cardiac cell monolayers

Lin¹,

Garber

et al. 2008

American Journal of Physiology-Heart and Circulatory Physiology

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in cardiac tissue is related to the occurrence of arrhythmias. Of importance are regions of slowed conduction, which have been implicated in the formation of conduction block and reentry. Experimentally, it has been a challenge to produce local heterogeneity in a manner that is both reversible and well controlled. Consequently, we developed a dual-zone superfusion chamber that can dynamically create a small (5 mm) central island of heterogeneity in cultured cardiac cell monolayers. Three different conditions were studied to explore the effect of regionally slowed conduction on wave propagation and reentry: depolarization by elevated extracellular potassium, sodium channel inhibition with lidocaine, and cell-cell decoupling with palmitoleic acid. Using optical mapping of transmembrane voltage, we found that the central region of slowed conduction always served as the core region around which a spiral wave formed and then revolved following a period of rapid pacing. Because of the localized slowing in the core region, we observed experimentally for the first time an S shape of the spiral wave front near its tip. These results indicate that a small region of slowed conduction can play a crucial role in the formation, anchoring, and modulation of reentrant spiral waves.

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Alternans and higher-order rhythms in an ionic model of a sheet of ischemic ventricular muscle

Cited by 30 publications

References 131 publications

A computationally efficient electrophysiological model of human ventricular cells

A computationally efficient electrophysiological model of human ventricular cells

Spatial heterogeneity of the restitution portrait in rabbit epicardium

Region of slowed conduction acts as core for spiral wave reentry in cardiac cell monolayers

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