Determinants of early afterdepolarization properties in ventricular myocyte models

AbstractEarly afterdepolarizations (EADs) are spontaneous depolarizations during the repolarization phase of an action potential in cardiac myocytes. It is widely known that EADs are promoted by increasing inward currents and/or decreasing outward currents, a condition called reduced repolarization reserve. Recent studies based on bifurcation theories show that EADs are caused by a dual Hopf-homoclinic bifurcation, bringing in further mechanistic insights into the genesis and dynamics of EADs. In this study, we investigated the EAD properties, such as the EAD amplitude, the inter-EAD interval, and the latency of the first EAD, and their major determinants. We first made predictions based on the bifurcation theory and then validated them in physiologically more detailed action potential models. These properties were investigated by varying one parameter at a time or using parameter sets randomly drawn from assigned intervals. The theoretical and simulation results were compared with experimental data from the literature. Our major findings are that the EAD amplitude and takeoff potential exhibit a negative linear correlation; the inter-EAD interval is insensitive to the maximum ionic current conductance but mainly determined by the kinetics of ICa,L and the dual Hopf-homoclinic bifurcation; and both inter-EAD interval and latency vary largely from model to model. Most of the model results generally agree with experimental observations in isolated ventricular myocytes. However, a major discrepancy between modeling results and experimental observations is that the inter-EAD intervals observed in experiments are mainly between 200 and 500 ms, irrespective of species, while those of the mathematical models exhibit a much wider range with some models exhibiting inter-EAD intervals less than 100 ms. Our simulations show that the cause of this discrepancy is likely due to the difference in ICa,L recovery properties in different mathematical models, which needs to be addressed in future action potential model development.Author summaryEarly afterdepolarizations (EADs) are abnormal depolarizations during the plateau phase of action potential in cardiac myocytes, arising from a dual Hopf-homoclinic bifurcation. The same bifurcations are also responsible for certain types of bursting behaviors in other cell types, such as beta cells and neuronal cells. EADs are known to play important role in the genesis of lethal arrhythmias and have been widely studied in both experiments and computer models. However, a detailed comparison between the properties of EADs observed in experiments and those from mathematical models have not been carried out. In this study, we performed theoretical analyses and computer simulations of different ventricular action potential models as well as different species to investigate the properties of EADs and compared these properties to those observed in experiments. While the EAD properties in the action potential models capture many of the EAD properties seen in experiments, the inter-EAD intervals in the computer models differ a lot from model to model, and some of them show very large discrepancy with those observed in experiments. This discrepancy needs to be addressed in future cardiac action potential model development.

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Modelos alométricos na determinação da área foliar de Bauhinia monandra Kurz

Comunicata Scientiae ◽

10.14295/cs.v7i3.1095 ◽

2016 ◽

Vol 7 (3) ◽

pp. 415

Author(s):

Edilson Romais Schmildt ◽

Omar Schmildt ◽

Rodrigo Sobreira Alexandre ◽

Adriano Alves Fernandes ◽

Marcio Paulo Czepak

Keyword(s):

Mathematical Models ◽

Leaf Area ◽

Linear Model ◽

Potential Model ◽

Leaf Surface ◽

Linear Quadratic ◽

Potential Models ◽

Independent Variables ◽

Model Based ◽

Area Determination

The aim of this study was to evaluate the efficiency of the adjustment of mathematical models for determining Bauhinia monandra leaf area using the length and/or width of the leaves as independent variables. Leaves from plants with three years were used to the estimative of equations in linear, quadratic and potential models. The validation from the estimated leaf area as a function of the observed leaf area showed that the linear model based on the product of length and width of the largest leaf surface is the model that best fits. However, the leaf area determination can be represented by using only the length or width of the leaves with little loss of accuracy. A representation that better estimates Bauhinia monandra leaf area with easy application is the potential model in which xi represents the length of one of the symmetrical leaf lobes.

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Local Onset of Voltage and Calcium Alternans in the Heart

ASME 2011 Dynamic Systems and Control Conference and Bath/ASME Symposium on Fluid Power and Motion Control, Volume 2 ◽

10.1115/dscc2011-6148 ◽

2011 ◽

Author(s):

Stephen D. McIntyre ◽

Yoichiro Mori ◽

Elena G. Tolkacheva

Keyword(s):

Ventricular Fibrillation ◽

Action Potential ◽

Intracellular Calcium ◽

Cardiac Myocytes ◽

Cardiac Tissue ◽

Potential Model ◽

Cardiac Action Potential ◽

2D Simulation ◽

Cardiac Action ◽

Electrical Alternans

A beat-to-beat variation in cardiac action potential durations (APD) is a phenomenon known as electrical alternans. Alternans desynchronizes depolarization, increases dispersion of refractoriness and creates a substrate for ventricular fibrillation. In the heart, APD alternans can be accompanied by alternans in intracellular calcium ([Ca2+]i) transients. Recently, we demonstrated experimentally that the onset of APD alternans in the heart is a local phenomenon that undergoes complex spatiotemporal dynamics as pacing rate increases. Moreover, the local onset of APD alternans can be predicted by measuring the restitution properties of periodically paced cardiac tissue. The purpose of this research is to investigate the interplay between local onsets of APD and [Ca2+]i alternans using 2D simulation of action potential model of cardiac myocytes.

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Can Phase-2 Early Afterdepolarizations Propagate in Cardiac Tissue? Insights from Multiple Action Potential Models

Biophysical Journal ◽

10.1016/j.bpj.2019.11.2317 ◽

2020 ◽

Vol 118 (3) ◽

pp. 409a-410a

Author(s):

Zhaoyang Zhang ◽

Michael B. Liu ◽

Zhen Song ◽

Zhilin Qu

Keyword(s):

Action Potential ◽

Cardiac Tissue ◽

Phase 2 ◽

Early Afterdepolarizations ◽

Potential Models

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Effects of early afterdepolarizations on reentry in cardiac tissue: a simulation study

AJP Heart and Circulatory Physiology ◽

10.1152/ajpheart.01309.2006 ◽

2007 ◽

Vol 292 (6) ◽

pp. H3089-H3102 ◽

Cited By ~ 22

Author(s):

Ray B. Huffaker ◽

James N. Weiss ◽

Boris Kogan

Keyword(s):

Action Potential ◽

Cardiac Tissue ◽

Genetic Diseases ◽

Three Dimensional ◽

New Wave ◽

Early Afterdepolarizations ◽

Heart Rates ◽

Torsades Des Pointes ◽

Repolarization Reserve ◽

Inward Currents

Early afterdepolarizations (EADs) are classically generated at slow heart rates when repolarization reserve is reduced by genetic diseases or drugs. However, EADs may also occur at rapid heart rates if repolarization reserve is sufficiently reduced. In this setting, spontaneous diastolic sarcoplasmic reticulum (SR) Ca release can facilitate cellular EAD formation by augmenting inward currents during the action potential plateau, allowing reactivation of the window L-type Ca current to reverse repolarization. Here, we investigated the effects of spontaneous SR Ca release-induced EADs on reentrant wave propagation in simulated one-, two-, and three-dimensional homogeneous cardiac tissue using a version of the Luo-Rudy dynamic ventricular action potential model modified to increase the likelihood of these EADs. We found: 1) during reentry, nonuniformity in spontaneous SR Ca release related to subtle differences in excitation history throughout the tissue created adjacent regions with and without EADs. This allowed EADs to initiate new wavefronts propagating into repolarized tissue; 2) EAD-generated wavefronts could propagate in either the original or opposite direction, as a single new wave or two new waves, depending on the refractoriness of tissue bordering the EAD region; 3) by suddenly prolonging local refractoriness, EADs caused rapid rotor displacement, shifting the electrical axis; and 4) rapid rotor displacement promoted self-termination by collision with tissue borders, but persistent EADs could regenerate single or multiple focal excitations that reinitiated reentry. These findings may explain many features of Torsades des pointes, such as perpetuation by focal excitations, rapidly changing electrical axis, frequent self-termination, and occasional degeneration to fibrillation.

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Contributions of inwardly rectifying K + currents to repolarization assessed using mathematical models of human ventricular myocytes

Philosophical Transactions of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rsta.2006.1765 ◽

2006 ◽

Vol 364 (1842) ◽

pp. 1207-1222 ◽

Cited By ~ 29

Author(s):

Martin Fink ◽

Wayne R Giles ◽

Denis Noble

Keyword(s):

Action Potential ◽

Mathematical Models ◽

Cardiac Electrophysiology ◽

Ventricular Myocytes ◽

Ionic Currents ◽

Normal Function ◽

Plateau Phase ◽

Repolarization Reserve ◽

Highly Nonlinear ◽

Inwardly Rectifying

Repolarization of the action potential (AP) in cardiac muscle is a major determinant of refractoriness and excitability, and can also strongly modulate excitation–contraction coupling. In clinical cardiac electrophysiology, the Q-T interval, and hence action potential duration, is both an essential marker of normal function and an indicator of risk for arrhythmic events. It is now well known that the termination of the plateau phase of the AP and the repolarization waveform involve a complex interaction of transmembrane ionic currents. These include a slowly inactivating Na + current, inactivating Ca 2+ current, the decline of an electrogenic current due to Na + /Ca 2+ exchange and activation of three or four different K + currents. At present, many of the quantitative aspects of this important physiological and pathophysiological process remain incompletely understood. Recently, three mathematical models of the membrane AP in human ventricle myocyte have been developed and made available on the Internet. In this study, we have implemented these models for the purpose of comparing the K + currents, which are responsible for terminating the plateau phase of the AP and generating its repolarization. In this paper, our emphasis is on the two highly nonlinear inwardly rectifying potassium currents, and . A more general goal is to obtain improved understanding of the ionic mechanisms, which underlie all-or-none repolarization and the parameter denoted ‘repolarization reserve’ in the human ventricle. Further, insights into these fundamental variables can be expected to provide a more rational basis for clinical assessment of the Q-T and Q-T C intervals, and hence provide insights into some of the very substantial efforts in safety pharmacology, which are based on these parameters.

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Characterization of the Electrophysiologic Remodeling of Patients With Ischemic Cardiomyopathy by Clinical Measurements and Computer Simulations Coupled With Machine Learning

Frontiers in Physiology ◽

10.3389/fphys.2021.684149 ◽

2021 ◽

Vol 12 ◽

Author(s):

Konstantinos N. Aronis ◽

Adityo Prakosa ◽

Teya Bergamaschi ◽

Ronald D. Berger ◽

Patrick M. Boyle ◽

...

Keyword(s):

Machine Learning ◽

Action Potential ◽

Ischemic Cardiomyopathy ◽

Model Development ◽

Tissue Level ◽

Potential Models ◽

Electrophysiological Properties ◽

Infarcted Myocardium ◽

Clinical Measurements

RationalePatients with ischemic cardiomyopathy (ICMP) are at high risk for malignant arrhythmias, largely due to electrophysiological remodeling of the non-infarcted myocardium. The electrophysiological properties of the non-infarcted myocardium of patients with ICMP remain largely unknown.ObjectivesTo assess the pro-arrhythmic behavior of non-infarcted myocardium in ICMP patients and couple computational simulations with machine learning to establish a methodology for the development of disease-specific action potential models based on clinically measured action potential duration restitution (APDR) data.Methods and ResultsWe enrolled 22 patients undergoing left-sided ablation (10 ICMP) and compared APDRs between ICMP and structurally normal left ventricles (SNLVs). APDRs were clinically assessed with a decremental pacing protocol. Using genetic algorithms (GAs), we constructed populations of action potential models that incorporate the cohort-specific APDRs. The variability in the populations of ICMP and SNLV models was captured by clustering models based on their similarity using unsupervised machine learning. The pro-arrhythmic potential of ICMP and SNLV models was assessed in cell- and tissue-level simulations. Clinical measurements established that ICMP patients have a steeper APDR slope compared to SNLV (by 38%, p < 0.01). In cell-level simulations, APD alternans were induced in ICMP models at a longer cycle length compared to SNLV models (385–400 vs 355 ms). In tissue-level simulations, ICMP models were more susceptible for sustained functional re-entry compared to SNLV models.ConclusionMyocardial remodeling in ICMP patients is manifested as a steeper APDR compared to SNLV, which underlies the greater arrhythmogenic propensity in these patients, as demonstrated by cell- and tissue-level simulations using action potential models developed by GAs from clinical measurements. The methodology presented here captures the uncertainty inherent to GAs model development and provides a blueprint for use in future studies aimed at evaluating electrophysiological remodeling resulting from other cardiac diseases.

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