A theory for the membrane potential of living cells

Endresen, Lars Petter; Hall, Kevin D.; Høye, Johan S.; Myrheim, Jan

doi:10.1007/s002490050254

Cited by 104 publications

(135 citation statements)

References 30 publications

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“…In the LRd model, drift is only observed when ions (usually K + ) that carry the stimulus current are not accounted for. If the stimulus is properly implemented and the ions that it carries are included in computing concentrations, no drift is observed even at fast pacing for long intervals When dynamic intracellular ion concentrations are accounted for, V m can also be computed directly from the concentrations by integrating the differential equation for voltage (see Varghese & Sell, 1997;Endresen et al 2000;Dokos & Lovell, 2001;Hund et al 2001 for details) to formulate the 'algebraic' method: 3. Ion-channel-based formulation of the action potential…”

Section: Cardiac Action Potential Modelsmentioning

confidence: 99%

“…The primary pump is the Na + /K + ATPase (NaK) that converts energy produced by the metabolic system into potential energy (in the form of transmembrane ion concentration gradients) that is used to generate the AP. (Faber & Rudy, 2000).Recently, there have been reports that the values of intracellular ion concentrations in secondgeneration AP models that account for dynamic concentration changes do not reach a steady state when paced over a long period of time, but drift until their values leave the physiological range (Guan et al 1997;Yehia et al 1999;Endresen et al 2000;Krogh-Madsen et al 2005). In the LRd model, drift is only observed when ions (usually K + ) that carry the stimulus current are not accounted for.…”

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confidence: 99%

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

Rudy

Silva

2006

Quart. Rev. Biophys.

239

181

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The 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. Prologue'Things should be made as simple as possible, but not any simpler.' Albert EinsteinCardiac muscle can generate propagating electrical impulses (action potentials), a property that classifies it as an excitable tissue similar to skeletal muscle and nerve. At the single-cell level, the electrical action potential (AP) triggers mechanical contraction by inducing a transient rise of intracellular calcium which, in turn, carries the contraction message to the contractile proteins of the cell. This process that couples electrical excitation to mechanical function is termed excitation-contraction coupling. APs are generated by individual cells and are conducted from cell to cell through intercellular gap junctions, forming waves of excitation that activate and synchronize the blood pumping action of the heart. Similar to nerve and skeletal muscle, AP initiation and conduction in cardiac ventricular tissue rely mostly on a single membrane process, namely the flow of sodium ions through sodium-specific ion channels. However, unlike the short-duration APs of skeletal muscle and nerve, the cardiac ventricular AP is characterized by long plateau and repolarization phases that prevent premature arrhythmogenic excitation and provide control of mechanical contraction. In NIH-PA Author ManuscriptNIH-PA Author Manuscript NIH-PA Author Manuscript contrast to the 'single-current mechanism' of...

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Section: Cardiac Action Potential Modelsmentioning

confidence: 99%

mentioning

confidence: 99%

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

Rudy

Silva

2006

Quart. Rev. Biophys.

239

181

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“…is much larger than that for N a + (Endresen et al, 2000). This implies that a significant background influx of Ca 2+ is possible during diastole, and that this current might be responsible for pacemaking activity in sinoatrial node cells (Boyett et al, 2001).…”

Section: +mentioning

confidence: 87%

“…The same model structure has been used in (Djabella and Sorine, 2005) to represent excitation-contraction coupling in a ventricular cell. It consists of two parts: 1) a cell membrane with capacitance, voltage-dependent ion channels, electrogenic pump and exchanger, the ionic currents model being derived using conservation laws as in (Endresen et al, 2000), and 2) a lumped compartmental model that accounts for intracellular changes in concentrations of N a Hund et al, 2001) and the main processes that regulate intracellular calcium concentration: release and uptake by the sarcoplasmic reticulum (SR), buffering in the SR (Tusscher et al, 2004) and in the bulk cytosol (Shannon et al, 2004).…”

Section: Introductionmentioning

confidence: 99%

A Differential Model of Controlled Cardiac Pacemaker Cell

Djabella

Sorine

2006

IFAC Proceedings Volumes

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A differential model of a cardiac pacemaker cell with only ten state variables is proposed. It is intended for 0D or 3D simulation of the heart under the vagal control of the autonomous nervous system. Three variables are used to describe the membrane (membrane potential and two gate variables of ionic channels), taking into account the dynamics of the main ionic currents (inward sodium, L-type calcium and outward potassium), N a + /Ca 2+ exchangers and N a + /K + pumps. The remaining seven variables are associated with the fluid compartment model that includes Ca 2+ binding by myoplasmic proteins, and the intracellular concentrations of free Calcium, Sodium and Potassium. Despite its moderate number of state variables, this model includes the main processes thought to be important in pacemaking on the cell scale and predicts the experimentally observed ionic concentration of calcium, sodium and potassium, action potential and membrane currents. The control by the calcium of the pacemaking activity is also considered.

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“…It has only eight state variables. Three variables are used to describe the membrane (membrane potential and two gate variables of ionic channels), taking into consideration the dynamics of the main ionic currents (inward sodium, Ltype calcium and outward potassium), Na + /Ca 2+ exchangers and Na + /K + pumps, derived using physical principles and conservation laws [6]. The remaining five variables are associated with the fluid compartment model accounting for intracellular changes in concentrations of Na + , K + [7] and the main processes that regulate intracellular calcium concentrations: release and uptake by the sarcoplasmic reticulum (SR), buffering in the SR [8] and in the bulk cytosol [9].…”

Section: Introductionmentioning

confidence: 99%

A Reduced Differential Model of the Electrical Activity of Cardiac Purkinje Fibres

Djabella

Sorine

2006

2006 International Conference of the IEEE Engineering in Medicine and Biology Society

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Abstract-A reduced order differential model of cardiac Purkinje fibres action potential, with only eight state variables, is presented. Its structure, derived from basic physical principles can be used for the main other cardiac cell types, a useful property for some model-based signal or image processing applications. The electrical activity of cardiac Purkinje fibres is reconstructed using particular values of the parameters. This model of the membrane excitation mechanism and intracellular calcium dynamics describes the principal ionic current underlying autorhythmicity; calcium uptake and release from the sarcoplasmic reticulum; effects of the binding of calcium on myoplasmic proteins which affect the Nernst potential of calcium, and then the membrane potential. The model allows realistic modelling of cardiac Purkinje fibres action potential, total ionic current, CICR dependence on intracellular calcium concentrations. Simulations illustrate the role of the inward sodium current as the dominant mechanism underlying pacemaker depolarization during spontaneous activity.

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A theory for the membrane potential of living cells

Cited by 104 publications

References 30 publications

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

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

A Differential Model of Controlled Cardiac Pacemaker Cell

A Reduced Differential Model of the Electrical Activity of Cardiac Purkinje Fibres

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