Quantitative techniques for steady-state calculation and dynamic integrated modelling of membrane potential and intracellular ion concentrations.

The membrane potential (E(m)) is a fundamental cellular parameter that is primarily determined by the transmembrane permeabilities and concentration gradients of various ions. However, ion gradients are themselves profoundly influenced by E(m) due to its influence upon transmembrane ion fluxes and cell volume (V(c)). These interrelationships between E(m), V(c) and intracellular ion concentrations make computational modelling useful or necessary in order to guide experimentation and to achieve an integrated understanding of experimental data, particularly in complex, dynamic, multi-compartment systems such as skeletal and cardiac myocytes. A variety of quantitative techniques exist that may assist such understanding, from classical approaches such as the Goldman-Hodgkin-Katz equation and the Gibbs-Donnan equilibrium, to more recent "current-summing" models as exemplified by cardiac myocyte models including those of DiFrancesco & Noble, Luo & Rudy and Puglisi & Bers, or the "charge-difference" modelling technique of Fraser & Huang so far applied to skeletal muscle. In general, the classical approaches provide useful and important insights into the relationships between E(m), V(c) and intracellular ion concentrations at steady state, providing their core assumptions are fully understood, while the more recent techniques permit the modelling of changing values of E(m), V(c) and intracellular ion concentrations. The present work therefore reviews the various approaches that may be used to calculate E(m), V(c) and intracellular ion concentrations with the aim of establishing the requirements for an integrated model that can both simulate dynamic systems and recapitulate the key findings of classical techniques regarding the cellular steady state. At a time when the number of cellular models is increasing at an unprecedented rate, it is hoped that this article will provide a useful and critical analysis of the mathematical techniques fundamental to each of them.

[1]  D DiFrancesco,et al.  A model of cardiac electrical activity incorporating ionic pumps and concentration changes. , 1985, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[2]  Clay M Armstrong,et al.  The Na/K pump, Cl ion, and osmotic stabilization of cells , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[3]  D. Maughan,et al.  Protein osmotic pressure and the state of water in frog myoplasm. , 2001, Biophysical journal.

[4]  A. Hodgkin,et al.  The influence of potassium and chloride ions on the membrane potential of single muscle fibres , 1959, The Journal of physiology.

[5]  A. Hodgkin,et al.  The effect of sodium ions on the electrical activity of the giant axon of the squid , 1949, The Journal of physiology.

[6]  D. E. Goldman POTENTIAL, IMPEDANCE, AND RECTIFICATION IN MEMBRANES , 1943, The Journal of general physiology.

[7]  Donald M Bers,et al.  A mathematical treatment of integrated Ca dynamics within the ventricular myocyte. , 2004, Biophysical journal.

[8]  T. Ogura,et al.  Sodium-pump potentials and currents in guinea-pig ventricular muscles and myocytes. , 1999, Canadian journal of physiology and pharmacology.

[9]  A. Weinstein Analysis of volume regulation in an epithelial cell model. , 1992, Bulletin of mathematical biology.

[10]  L. Mullins,et al.  The Influence of Sodium-Free Solutions on the Membrane Potential of Frog Muscle Fibers , 1963, The Journal of general physiology.

[11]  C. Huang,et al.  The effect of intracellular acidification on the relationship between cell volume and membrane potential in amphibian skeletal muscle , 2005, The Journal of physiology.

[12]  A. Verkman Water channels in cell membranes. , 1992, Annual review of physiology.

[13]  F Sachs,et al.  Stretch‐activated single ion channel currents in tissue‐cultured embryonic chick skeletal muscle. , 1984, The Journal of physiology.

[14]  G. Sjøgaard,et al.  Water and ion shifts in skeletal muscle of humans with intense dynamic knee extension. , 1985, The American journal of physiology.

[15]  J C SKOU,et al.  The influence of some cations on an adenosine triphosphatase from peripheral nerves. , 1957, Biochimica et biophysica acta.

[16]  J L Puglisi,et al.  LabHEART: an interactive computer model of rabbit ventricular myocyte ion channels and Ca transport. , 2001, American journal of physiology. Cell physiology.

[17]  C. Luo,et al.  A dynamic model of the cardiac ventricular action potential. I. Simulations of ionic currents and concentration changes. , 1994, Circulation research.

[18]  R. Moreton An investigation of the electrogenic sodium pump in snail neurones, using the constant-field theory. , 1969, The Journal of experimental biology.

[19]  G. W. Beeler,et al.  Reconstruction of the action potential of ventricular myocardial fibres , 1977, The Journal of physiology.

[20]  J. Fraser,et al.  A quantitative analysis of cell volume and resting potential determination and regulation in excitable cells , 2004, The Journal of physiology.

[21]  W. Giles,et al.  Comparison of steady-state electrophysiological properties of isolated cells from bullfrog atrium and sinus venous , 2005, The Journal of Membrane Biology.

[22]  Elliot Gf Donnan and osmotic effects in muscle fibres without membranes. , 1973 .

[23]  T. Clausen Na+-K+ pump regulation and skeletal muscle contractility. , 2003, Physiological reviews.

[24]  A. Hodgkin,et al.  Measurement of current‐voltage relations in the membrane of the giant axon of Loligo , 1952, The Journal of physiology.

[25]  D. Bers,et al.  Surface:volume relationship in cardiac myocytes studied with confocal microscopy and membrane capacitance measurements: species-dependence and developmental effects. , 1996, Biophysical journal.

[26]  B. L. Ginsborg,et al.  The ionic requirements for the production of action potentials in crustacean muscle fibres , 1958, The Journal of physiology.

[27]  R. Thomas,et al.  Electrogenic sodium pump in nerve and muscle cells. , 1972, Physiological reviews.

[28]  D. Maughan,et al.  Diffusible sodium, potassium, magnesium, calcium and phosphorus in frog skeletal muscle. , 1985, The Journal of physiology.

[29]  Markus Ritter,et al.  Mechanisms Sensing and Modulating Signals Arising From Cell Swelling , 2002, Cellular Physiology and Biochemistry.

[30]  E. Conway,et al.  Potassium accumulation in muscle and associated changes 1 , 1941 .

[31]  G. Tomaselli,et al.  Electrophysiological remodeling in hypertrophy and heart failure. , 1999, Cardiovascular research.

[32]  Stanley Nattel,et al.  Time-dependent transients in an ionically based mathematical model of the canine atrial action potential. , 2002, American journal of physiology. Heart and circulatory physiology.

[33]  D. Noble A modification of the Hodgkin—Huxley equations applicable to Purkinje fibre action and pacemaker potentials , 1962, The Journal of physiology.

[34]  E. A. Pask,et al.  Monographs of the Physiological Society , 1956 .

[35]  B. Stambler,et al.  Persistent activation of a swelling-activated cation current in ventricular myocytes from dogs with tachycardia-induced congestive heart failure. , 1998, Circulation research.

[36]  J. Jacquez A generalization of the Goldman equation, including the effect of electrogenic pumps , 1971 .

[37]  T. Clausen The Sodium Pump Keeps Us Going , 2003, Annals of the New York Academy of Sciences.

[38]  D. Häussinger,et al.  Functional significance of cell volume regulatory mechanisms. , 1998, Physiological reviews.

[39]  Virgilio L. Lew,et al.  Volume, pH, and ion-content regulation in human red cells: Analysis of transient behavior with an integrated model , 2005, The Journal of Membrane Biology.

[40]  C. Huang,et al.  Slow volume transients in amphibian skeletal muscle fibres studied in hypotonic solutions , 2005, The Journal of physiology.

[41]  F. Lang,et al.  The Diversity of Volume Regulatory Mechanisms , 1998, Cellular Physiology and Biochemistry.

[42]  E Jakobsson,et al.  Interactions of cell volume, membrane potential, and membrane transport parameters. , 1980, The American journal of physiology.

[43]  D. Noble,et al.  Reconstruction of the electrical activity of cardiac Purkinje fibres. , 1975, The Journal of physiology.

[44]  G Sjøgaard,et al.  Dynamics and consequences of potassium shifts in skeletal muscle and heart during exercise. , 2000, Physiological reviews.

[45]  C. Luo,et al.  A model of the ventricular cardiac action potential. Depolarization, repolarization, and their interaction. , 1991, Circulation research.

[46]  Takahiro Shimizu,et al.  Receptor‐mediated control of regulatory volume decrease (RVD) and apoptotic volume decrease (AVD) , 2001, The Journal of physiology.

[47]  C. Luo,et al.  A dynamic model of the cardiac ventricular action potential. II. Afterdepolarizations, triggered activity, and potentiation. , 1994, Circulation research.

[48]  R. Winslow,et al.  Electrophysiological modeling of cardiac ventricular function: from cell to organ. , 2000, Annual review of biomedical engineering.

[49]  W. C. O'Neill,et al.  Physiological significance of volume-regulatory transporters. , 1999, American journal of physiology. Cell physiology.

[50]  R. Post,et al.  The linkage of sodium, potassium, and ammonium active transport across the human erythrocyte membrane. , 1957, Biochimica et biophysica acta.

[51]  E. Conway Nature and significance of concentration relations of potassium and sodium ions in skeletal muscle. , 1957, Physiological reviews.

[52]  C. Baumgarten,et al.  Swelling-activated chloride channels in cardiac physiology and pathophysiology. , 2003, Progress in biophysics and molecular biology.

[53]  W. F. Hamilton,et al.  Handbook of Physiology. Section- 2 , 1967 .

[54]  D. Chang Dependence of cellular potential on ionic concentrations. Data supporting a modification of the constant field equation. , 1983, Biophysical journal.

[55]  O. Ortiz,et al.  Resolution of the potassium ion pump in muscle fibers using barium ions , 1975, The Journal of general physiology.

[56]  L. Liebovitch,et al.  Kinetic model of the effects of electrogenic enzymes on the membrane potential. , 1989, Journal of theoretical biology.

[57]  D. Motlagh,et al.  Form follows function: how muscle shape is regulated by work. , 2000, Journal of applied physiology.

[58]  Jose L Puglisi,et al.  Modeling the isolated cardiac myocyte. , 2004, Progress in biophysics and molecular biology.

[59]  I. Matsubara,et al.  X-ray diffraction studies on skinned single fibres of frog skeletal muscle. , 1972, Journal of molecular biology.