Markov modeling provides an effective approach for modeling ion channel kinetics. There are several search algorithms for global fitting of macroscopic or single-channel currents across different experimental conditions. Here we present a particle swarm optimization(PSO)-based approach which, when used in combination with golden section search (GSS), can fit macroscopic voltage responses with a high degree of accuracy (errors within 1%) and reasonable amount of calculation time (less than 10 hours for 20 free parameters) on a desktop computer. We also describe a method for initial value estimation of the model parameters, which appears to favor identification of global optimum and can further reduce the computational cost. The PSO-GSS algor...
Understanding the roles of ion currents is crucial to predict the action of pharmaceuticals and muta...
© 2019 Biophysical Society Mathematical models of ionic currents are used to study the electrophysio...
Mathematical models of ionic currents are used to study the electrophysiology of the heart, brain, g...
Markov modeling provides an effective approach for modeling ion channel kinetics. There are several ...
AbstractWe describe a maximum likelihood method for direct estimation of rate constants from macrosc...
Quantitative ion channel model evaluation requires the estimation of voltage dependent rate constant...
Computational models of ion channels represent the building blocks of conductance-based, biologicall...
AbstractFor single channel recordings, the maximum likelihood estimation (MLE) of kinetic rates and ...
Computational models of cardiac electrophysiology provided insights into arrhythmogenesis and paved ...
In this work, we propose a methodology based on Monte Carlo Markov chains to explore the parameter s...
Markov models (MMs) represent a generalization of Hodgkin-Huxley models. They provide a versatile st...
Estimation of the maximal ion channel conductances in Hodgkin-Huxley models from patch clamp data is...
Cardiac electrophysiological computational models are often developed from previously published mode...
Cardiac electrophysiological computational models are often developed from previously published mode...
AbstractHidden Markov modeling (HMM) provides an effective approach for modeling single channel kine...
Understanding the roles of ion currents is crucial to predict the action of pharmaceuticals and muta...
© 2019 Biophysical Society Mathematical models of ionic currents are used to study the electrophysio...
Mathematical models of ionic currents are used to study the electrophysiology of the heart, brain, g...
Markov modeling provides an effective approach for modeling ion channel kinetics. There are several ...
AbstractWe describe a maximum likelihood method for direct estimation of rate constants from macrosc...
Quantitative ion channel model evaluation requires the estimation of voltage dependent rate constant...
Computational models of ion channels represent the building blocks of conductance-based, biologicall...
AbstractFor single channel recordings, the maximum likelihood estimation (MLE) of kinetic rates and ...
Computational models of cardiac electrophysiology provided insights into arrhythmogenesis and paved ...
In this work, we propose a methodology based on Monte Carlo Markov chains to explore the parameter s...
Markov models (MMs) represent a generalization of Hodgkin-Huxley models. They provide a versatile st...
Estimation of the maximal ion channel conductances in Hodgkin-Huxley models from patch clamp data is...
Cardiac electrophysiological computational models are often developed from previously published mode...
Cardiac electrophysiological computational models are often developed from previously published mode...
AbstractHidden Markov modeling (HMM) provides an effective approach for modeling single channel kine...
Understanding the roles of ion currents is crucial to predict the action of pharmaceuticals and muta...
© 2019 Biophysical Society Mathematical models of ionic currents are used to study the electrophysio...
Mathematical models of ionic currents are used to study the electrophysiology of the heart, brain, g...