scholarly journals Four ways to fit an ion channel model

2019 ◽  
Author(s):  
M. Clerx ◽  
K.A. Beattie ◽  
D.J. Gavaghan ◽  
G.R. Mirams
Keyword(s):  
Action Potential ◽  
Ion Channel ◽  
Voltage Clamp ◽  
Time Constant ◽  
Cardiac Action Potential ◽  
Channel Kinetics ◽  
Safety Critical ◽  
Independent Validation ◽  
Cardiac Action ◽  
Ion Channel Kinetics

ABSTRACTComputational models of the cardiac action potential are increasingly being used to investigate the effects of genetic mutations, predict pro-arrhythmic risk in drug development, and to guide clinical interventions. These safety-critical applications, and indeed our understanding of the cardiac action potential, depend on accurate characterisation of the underlying ionic currents. Four different methods can be found in the literature to fit ionic current models to single-cell measurements: (Method 1) fitting model equations directly to time constant, steady-state, and I-V summary curves; (Method 2) fitting by comparing simulated versions of these summary curves to their experimental counterparts; (Method 3) fitting to the current traces themselves from a range of protocols; and (Method 4) fitting to a single current trace from an information-rich voltage clamp protocol. We compare these methods using a set of experiments in which hERG1a current from single Chinese Hamster Ovary (CHO) cells was characterised using multiple fitting protocols and an independent validation protocol. We show that Methods 3 and 4 provide the best predictions on the independent validation set, and that the short information-rich protocols of Method 4 can replace much longer conventional protocols without loss of predictive ability. While data for Method 2 is most readily available from the literature, we find it performs poorly compared to Methods 3 and 4 both in accuracy of predictions and computational efficiency. Our results demonstrate how novel experimental and computational approaches can improve the quality of model predictions in safety-critical applications.Statement of SignificanceMathematical models have been constructed to capture and share our understanding of the kinetics of ion channel currents for almost 70 years, and hundreds of models have been developed, using a variety of techniques. We compare how well four of the main methods fit data, how reliable and efficient the process of fitting is, and how predictive the resulting models are for physiological situations. The most widely-used traditional approaches based on current-voltage and time constant-voltage curves do not produce the most predictive models. Short, optimised experimental voltage clamp protocols can be used to create models that are as predictive as ones derived from traditional protocols, opening up possibilities for measuring ion channel kinetics faster, more accurately and in single cells. As these models often form part of larger multi-scale action potential and tissue electrophysiology models, improved ion channel kinetics models could influence the findings of thousands of simulation studies.

scholarly journals Computational biology in the study of cardiac ion channels and cell electrophysiology

2006 ◽  
Vol 39 (1) ◽  
pp. 57-116 ◽  
Author(s):  
Yoram Rudy ◽  
Jonathan R. Silva
Keyword(s):  
Ion Channels ◽  
Action Potential ◽  
Ion Channel ◽  
Markov Models ◽  
Cardiac Action Potential ◽  
Genetic Mutations ◽  
Cardiac Ion Channels ◽  
Cardiac Action ◽  
Ion Channel Kinetics

1. Prologue 582. The Hodgkin–Huxley formalism for computing the action potential 592.1 The axon action potential model 592.2 Cardiac action potential models 623. Ion-channel based formulation of the action potential 653.1 Ion-channel structure 653.2 Markov models of ion-channel kinetics 663.3 Role of selected ion channels in rate dependence of the cardiac action potential 713.4 Physiological implications of IKs subunit interaction 773.5 Mechanism of cardiac action potential rate-adaptation is species dependent 784. Simulating ion-channel mutations and their electrophysiological consequences 814.1 Mutations in SCN5A, the gene that encodes the cardiac sodium channel 824.1.1 The ΔKPQ mutation and LQT3 824.1.2 SCN5A mutation that underlies a dual phenotype 874.2 Mutations in HERG, the gene that encodes IKr: re-examination of the ‘gain of function/loss of function’ concept 944.3 Role of IKs as ‘repolarization reserve’ 1005. Modeling cell signaling in electrophysiology 1025.1 CaMKII regulation of the Ca2+ transient 1025.2 The β-adrenergic signaling cascade 1056. Epilogue 1077. Acknowledgments 1088. References 109The cardiac cell is a complex biological system where various processes interact to generate electrical excitation (the action potential, AP) and contraction. During AP generation, membrane ion channels interact nonlinearly with dynamically changing ionic concentrations and varying transmembrane voltage, and are subject to regulatory processes. In recent years, a large body of knowledge has accumulated on the molecular structure of cardiac ion channels, their function, and their modification by genetic mutations that are associated with cardiac arrhythmias and sudden death. However, ion channels are typically studied in isolation (in expression systems or isolated membrane patches), away from the physiological environment of the cell where they interact to generate the AP. A major challenge remains the integration of ion-channel properties into the functioning, complex and highly interactive cell system, with the objective to relate molecular-level processes and their modification by disease to whole-cell function and clinical phenotype. In this article we describe how computational biology can be used to achieve such integration. We explain how mathematical (Markov) models of ion-channel kinetics are incorporated into integrated models of cardiac cells to compute the AP. We provide examples of mathematical (computer) simulations of physiological and pathological phenomena, including AP adaptation to changes in heart rate, genetic mutations in SCN5A and HERG genes that are associated with fatal cardiac arrhythmias, and effects of the CaMKII regulatory pathway and β-adrenergic cascade on the cell electrophysiological function.

scholarly journals Sinusoidal voltage protocols for rapid characterisation of ion channel kinetics

2017 ◽  
Author(s):  
Kylie A. Beattie ◽  
Adam P. Hill ◽  
Rémi Bardenet ◽  
Yi Cui ◽  
Jamie I. Vandenberg ◽  
...  
Keyword(s):  
Ion Channel ◽  
Voltage Clamp ◽  
Ion Current ◽  
Ion Currents ◽  
Channel Kinetics ◽  
Sinusoidal Voltage ◽  
Square Wave ◽  
Voltage Clamps ◽  
Ion Channel Kinetics ◽  
Cell Cell

AbstractUnderstanding the roles of ion currents is crucial to predict the action of pharmaceuticals and mutations in different scenarios, and thereby to guide clinical interventions in the heart, brain and other electrophysiological systems. Our ability to predict how ion currents contribute to cellular electrophysiology is in turn critically dependent on our characterisation of ion channel kinetics — the voltage-dependent rates of transition between open, closed and inactivated channel states. We present a new method for rapidly exploring and characterising ion channel kinetics, applying it to the hERG potassium channel as an example, with the aim of generating a quantitatively predictive representation of the ion current. We fit a mathematical model to currents evoked by a novel 8 second sinusoidal voltage clamp in CHO cells over-expressing hERG1a. The model is then used to predict over 5 minutes of recordings in the same cell in response to further protocols: a series of traditional square step voltage clamps, and also a novel voltage clamp comprised of a collection of physiologically-relevant action potentials. We demonstrate that we can make predictive cell-specific models that outperform the use of averaged data from a number of different cells, and thereby examine which changes in gating are responsible for cell-cell variability in current kinetics. Our technique allows rapid collection of consistent and high quality data, from single cells, and produces more predictive mathematical ion channel models than traditional approaches.Table of Contents CategoryTechniques for Physiology1Key PointsIon current kinetics are commonly represented by current-voltage relationships, time-constant voltage relationships, and subsequently mathematical models fitted to these. These experiments take substantial time which means they are rarely performed in the same cell.Rather than traditional square-wave voltage clamps, we fit a model to the current evoked by a novel sum-of-sinusoids voltage clamp that is only 8 seconds long.Short protocols that can be performed multiple times within a single cell will offer many new opportunities to measure how ion current kinetics are affected by changing conditions.The new model predicts the current under traditional square-wave protocols well, with better predictions of underlying currents than literature models. The current under a novel physiologically-relevant series of action potential clamps is predicted extremely well.The short sinusoidal protocols allow a model to be fully fitted to individual cells, allowing us to examine cell-cell variability in current kinetics for the first time.

SIMPLE EXPERIMENTS TO UNDERSTAND THE IONIC ORIGINS AND CHARACTERISTICS OF THE VENTRICULAR CARDIAC ACTION POTENTIAL

2002 ◽  
Vol 26 (3) ◽  
pp. 185-194 ◽  
Author(s):  
Jean-Yves Le Guennec ◽  
Christophe Vandier ◽  
Gilles Bedfer
Keyword(s):  
Action Potential ◽  
Electrical Activity ◽  
Voltage Clamp ◽  
Undergraduate Students ◽  
Papillary Muscle ◽  
Action Potentials ◽  
Heart Function ◽  
Cardiac Action Potential ◽  
Extracellular Potassium ◽  
Cardiac Action

Electrophysiological experiments are helpful for students to understand the role of electrical activity in heart function. Papillary muscle, which belongs to the ventricle, offers the advantage of being easily studied using glass microelectrodes. In addition, there is commercially available software that simulates ventricular electrical activity and can help overcome some difficulties, such as voltage clamp experiments, which need expensive apparatus when used for studies on living preparations. Here, we present a class practical session that is taken by undergraduate students at our University. In the first part of this class, students record action potentials from papillary muscles with the use of glass microelectrodes, and they change extracellular conditions to study the ionic basis of the action potential. In the second part of the class, students simulate action potentials using the Oxsoft Heart model (v. 4.0) and model their previous experiments on papillary muscle to quantify the effects. In particular, the model is very helpful in promoting understanding of the effect that extracellular potassium has on cardiac action potential by simulating voltage clamp experiments. This twin approach of papillary muscle experiments and computer modeling leads to a good understanding of the functioning of the action potential and can help introduce discussion of some abnormal cardiac functioning.

scholarly journals Modulation of the Cardiac Myocyte Action Potential by the Magnesium-Sensitive TRPM6 and TRPM7-like Current

2021 ◽  
Vol 22 (16) ◽  
pp. 8744
Author(s):  
Asfree Gwanyanya ◽  
Inga Andriulė ◽  
Bogdan M. Istrate ◽  
Farjana Easmin ◽  
Kanigula Mubagwa ◽  
...  
Keyword(s):  
Patch Clamp ◽  
Action Potential ◽  
Voltage Clamp ◽  
Divalent Cation ◽  
Cardiac Myocyte ◽  
Cardiac Action Potential ◽  
Delayed Rectifier ◽  
Delayed Rectifier Current ◽  
Cardiac Action ◽  
In Cells

The cardiac Mg2+-sensitive, TRPM6, and TRPM7-like channels remain undefined, especially with the uncertainty regarding TRPM6 expression in cardiomyocytes. Additionally, their contribution to the cardiac action potential (AP) profile is unclear. Immunofluorescence assays showed the expression of the TRPM6 and TRPM7 proteins in isolated pig atrial and ventricular cardiomyocytes, of which the expression was modulated by incubation in extracellular divalent cation-free conditions. In patch clamp studies of cells dialyzed with solutions containing zero intracellular Mg2+ concentration ([Mg2+]i) to activate the Mg2+-sensitive channels, raising extracellular [Mg2+] ([Mg2+]o) from the 0.9-mM baseline to 7.2 mM prolonged the AP duration (APD). In contrast, no such effect was observed in cells dialyzed with physiological [Mg2+]i. Under voltage clamp, in cells dialyzed with zero [Mg2+]i, depolarizing ramps induced an outward-rectifying current, which was suppressed by raising [Mg2+]o and was absent in cells dialyzed with physiological [Mg2+]i. In cells dialyzed with physiological [Mg2+]i, raising [Mg2+]o decreased the L-type Ca2+ current and the total delayed-rectifier current but had no effect on the APD. These results suggest a co-expression of the TRPM6 and TRPM7 proteins in cardiomyocytes, which are therefore the molecular candidates for the native cardiac Mg2+-sensitive channels, and also suggest that the cardiac Mg2+-sensitive current shortens the APD, with potential implications in arrhythmogenesis.

scholarly journals A multiscale model linking ion-channel molecular dynamics and electrostatics to the cardiac action potential

2009 ◽  
Vol 106 (27) ◽  
pp. 11102-11106 ◽  
Author(s):  
J. R. Silva ◽  
H. Pan ◽  
D. Wu ◽  
A. Nekouzadeh ◽  
K. F. Decker ◽  
...  
Keyword(s):  
Molecular Dynamics ◽  
Action Potential ◽  
Ion Channel ◽  
Multiscale Model ◽  
Cardiac Action Potential ◽  
Cardiac Action
Sign in / Sign up

Export Citation Format

Share Document