Ryan A. Devenyi scite author profile

Imbalances of ionic currents can destabilize the cardiac action potential and potentially trigger lethal cardiac arrhythmias. In the present study, we combined mathematical modelling with information-rich dynamic clamp experiments to determine the regulation of action potential morphology in guinea pig ventricular myocytes. Parameter sensitivity analysis was used to predict how changes in ionic currents alter action potential duration, and these were tested experimentally using dynamic clamp, a technique that allows for multiple perturbations to be tested in each cell. Surprisingly, we found that a leading mathematical model, developed with traditional approaches, systematically underestimated experimental responses to dynamic clamp perturbations. We then re-parameterized the model using a genetic algorithm, which allowed us to estimate ionic current levels in each of the cells studied. This unbiased model adjustment consistently predicted an increase in the rapid delayed rectifier K current and a drastic decrease in the slow delayed rectifier K current, and this prediction was validated experimentally. Subsequent simulations with the adjusted model generated the clinically relevant prediction that the slow delayed rectifier is better able to stabilize the action potential and suppress pro-arrhythmic events than the rapid delayed rectifier. In summary, iterative coupling of simulations and experiments enabled novel insight into how the balance between cardiac K currents influences ventricular arrhythmia susceptibility.

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There and back again: Iterating between population-based modeling and experiments reveals surprising regulation of calcium transients in rat cardiac myocytes

Devenyi

Sobie

2016

Journal of Molecular and Cellular Cardiology

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While many ion channels and transporters involved in cardiac cellular physiology have been identified and described, the relative importance of each in determining emergent cellular behaviors remains unclear. Here we address this issue with a novel approach that combines population-based mathematical modeling with experimental tests to systematically quantify the relative contributions of different ion channels and transporters to the amplitude of the cellular Ca2+ transient. Sensitivity analysis of a mathematical model of the rat ventricular cardiomyocyte quantified the response of cell behaviors to changes in the level of each ion channel and transporter, and experimental tests of these predictions were performed to validate or invalidate the predictions. The model analysis found that partial inhibition of transient outward current in rat ventricular epicardial myocytes was predicted to have a greater impact on Ca2+ transient amplitude than either: (1) inhibition of the same current in endocardial myocytes, or (2) comparable inhibition of the sarco/endoplasmic reticulum Ca2+ ATPase (SERCA). Experimental tests confirmed the model predictions qualitatively but showed some quantitative disagreement. This guided us to recalibrate the model by adjusting the relative importance of several Ca2+ fluxes, thereby improving the consistency with experimental data and producing a more predictive model. Analysis of human cardiomyocyte models suggests that the relative importance of outward currents to Ca2+ transporters is generalizable to human atrial cardiomyocytes, but not ventricular cardiomyocytes. Overall, our novel approach of combining population-based mathematical modeling with experimental tests has yielded new insight into the relative importance of different determinants of cell behavior.

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Slow Delayed Rectifier Current Protects Ventricular Myocytes From Arrhythmic Dynamics Across Multiple Species

Varshneya

Devenyi

Sobie

2018

Circ: Arrhythmia and Electrophysiology

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BACKGROUND: The slow and rapid delayed rectifier K+ currents (IKs and IKr, respectively) are responsible for repolarizing the ventricular action potential (AP) and preventing abnormally long APs that may lead to arrhythmias. Although differences in biophysical properties of the two currents have been carefully documented, the respective physiological roles of IKr and IKs are less established. In this study, we sought to understand the individual roles of these currents and quantify how effectively each stabilizes the AP and protects cells against arrhythmias across multiple species. METHODS: We compared 10 mathematical models describing ventricular myocytes from human, rabbit, canine, and guinea pig. We examined variability within heterogeneous cell populations, tested the susceptibility of cells to proarrhythmic behavior, and studied how IKs and IKr responded to changes in the AP. RESULTS: We found that: (1) models with higher baseline IKs exhibited less cell-to-cell variability in action potential duration (APD); (2) models with higher baseline IKs were less susceptible to early afterdepolarizations (EADs) induced by depolarizing perturbations; (3) as APD is lengthened, IKs increases more profoundly than IKr, thereby providing negative feedback that resists excessive AP prolongation; and (4) the increase in IKs that occurs during β-adrenergic stimulation is critical for protecting cardiac myocytes from EADs under these conditions. CONCLUSIONS: Slow delayed rectifier current is uniformly protective across a variety of cell types. These results suggest that IKs enhancement could potentially be an effective antiarrhythmic strategy.

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Yoga for the sinoatrial node: Sarcoplasmic reticulum calcium release confers flexibility

Cummins¹,

Devenyi²,

Sobie³

2013

Journal of Molecular and Cellular Cardiology

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Population-Based Mathematical Modeling Facilitates the Interpretation of Dynamic Clamp Experiments in Cardiomyocytes

Devenyi

Ortega

Krogh‐Madsen

et al. 2016

Biophysical Journal

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Ryan A. Devenyi

Differential roles of two delayed rectifier potassium currents in regulation of ventricular action potential duration and arrhythmia susceptibility

There and back again: Iterating between population-based modeling and experiments reveals surprising regulation of calcium transients in rat cardiac myocytes

Slow Delayed Rectifier Current Protects Ventricular Myocytes From Arrhythmic Dynamics Across Multiple Species

Yoga for the sinoatrial node: Sarcoplasmic reticulum calcium release confers flexibility

Population-Based Mathematical Modeling Facilitates the Interpretation of Dynamic Clamp Experiments in Cardiomyocytes

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