Electrophysiology

Adrian, Peachey, 1973: Reconstruction of the action potential of frog sartorius muscle
Albrecht, Colegrove, Friel, 2002: Differential Regulation of ER Ca2+ Uptake and Release Rates Accounts for Multiple Modes of Ca2+-induced Ca2+ Release
Albrecht, Colegrove, Hongpaisan, Pivovarova, Andrews, Friel, 2001: Multiple Modes of Calcium-induced Calcium Release in Sympathetic Neurons I: Attenuation of Endoplasmic Reticulum Ca2+ Accumulation at Low [Ca2+]i during Weak Depolarisation
Aslanidi, Boyett, Dobrzynski, Li, Zhang, 2009: Mechanisms of transition from normal to reentrant electrical activity in a model of rabbit atrial tissue: interaction of tissue heterogeneity and anisotropy
Aslanidi, Stewart, Boyett, Zhang, 2009: Optimal velocity and safety of discontinuous conduction through the heterogeneous Purkinje-ventricular junction
Beeler, Reuter, 1977: Reconstruction of the action potential of ventricular myocardial fibres
Beeler, Reuter, 1977: Reconstruction of the action potential of ventricular myocardial fibres, with modifications to demonstrate uncertainty.
Benson, Aslanidi, Zhang, Holden, 2008: The canine virtual ventricular wall: a platform for dissecting pharmacological effects on propagation and arrhythmogenesis (Epicardial Cell Model)
Benson, Aslanidi, Zhang, Holden, 2008: The canine virtual ventricular wall: a platform for dissecting pharmacological effects on propagation and arrhythmogenesis (Endocardial Cell Model)
Benson, Aslanidi, Zhang, Holden, 2008: The canine virtual ventricular wall: a platform for dissecting pharmacological effects on propagation and arrhythmogenesis (Midmyocardial Cell Model)
Bernus, Wilders, Zemlin, Verschelde, Panfilov, 2002: A computationally efficient electrophysiological model of human ventricular cells
Bertram, Arnot, Zamponi, 2002: Role for G protein G-beta-gamma isoform specificity in synaptic signal processing (Pre-Synaptic Cell)
Bertram, Arnot, Zamponi, 2002: Role for G protein G-beta-gamma isoform specificity in synaptic signal processing (Post-Synaptic Cell)
Bertram, Pedersen, Luciani, Sherman, 2006: A simplified model for mitochondrial ATP production
Bertram, Previte, Sherman, Kinard, Satin, 2000: The Phantom Burster Model for Pancreatic Beta Cells (fast bursting model)
Bertram, Previte, Sherman, Kinard, Satin, 2000: The Phantom Burster Model for Pancreatic Beta Cells (medium bursting model)
Bertram, Previte, Sherman, Kinard, Satin, 2000: The Phantom Burster Model for Pancreatic Beta Cells (slow bursting model)
Bertram, Rhoads, Cimbora, 2008: A phantom bursting mechanism for episodic bursting: original model
Bertram, Rhoads, Cimbora, 2008: A phantom bursting mechanism for episodic bursting: modified to include channel noise in the leak current
Bertram, Sherman, 2004: A Calcium-based Phantom Bursting Model for Pancreatic Islets
Bertram, Smolen, Sherman, Mears, Atwater, Martin, Soria, 1995: A role for calcium release-activated current (CRAC) in cholinergic modulation of electrical activity in pancreatic beta-cells
Bondarenko, Szigeti, Bett, Kim, Rasmusson, 2004: Computer model of action potential of mouse ventricular myocytes (Apical Cell Description)
Bondarenko, Szigeti, Bett, Kim, Rasmusson, 2004: Computer model of action potential of mouse ventricular myocytes (Septal Cell Description)
Boyett, Zhang, Garny, Holden, 2001: Control of the pacemaker activity of the sinoatrial node by intracellular Ca2+. Experiments and modelling
Bueno, 2007: Mathematical modeling and spectral simulation of genetic diseases in the human heart
Butera, Rinzel, Smith, 1999: Models of Respiratory Rhythm Generation in the Pre-Botzinger Complex. I. Bursting Pacemaker Neurons: model 1 (which does not include a slow potassium current)
Butera, Rinzel, Smith, 1999: Models of Respiratory Rhythm Generation in the Pre-Botzinger Complex. I. Bursting Pacemaker Neurons: model 2 (which includes a slow potassium current)
Chang, Fujita, 1999: A numerical model of the renal distal tubule
Chang, Fujita, 1999: A kinetic model of the thiazide-sensitive Na-Cl cotransporter
Chang, Fujita, 2001: H-ATPase
Chang, Fujita, 2001: Na-H exchanger
Chang, Fujita, 2001: Anion exchanger
Chay, 1997: Effects of extracellular calcium on electrical bursting and intracellular and luminal calcium oscillations in insulin secreting pancreatic beta-cells
Chay, Lee, Fan, 1995: Appearance of Phase-locked Wenchbach-like Rhythms, Devil's Staircase and Universality in Intracellular Calcium Spikes in Non-excitable Cell Models
Clancy, Rudy, 2001: Cellular consequences of HERG mutations in the long QT syndrome: precursors to sudden cardiac death (Wild Type Epicardial Cell)
Clancy, Rudy, 2001: Cellular consequences of HERG mutations in the long QT syndrome: precursors to sudden cardiac death (IKrN629D Mutant Epicardial Cell)
Clancy, Rudy, 2001: Cellular consequences of HERG mutations in the long QT syndrome: precursors to sudden cardiac death (IKr629D Mutant Midmyocardial Cell)
Clancy, Rudy, 2001: Cellular consequences of HERG mutations in the long QT syndrome: precursors to sudden cardiac death (IKrR56Q Mutant Epicardial Cell)
Clancy, Rudy, 2001: Cellular consequences of HERG mutations in the long QT syndrome: precursors to sudden cardiac death (IKrR56Q Mutant Midmyocardial Cell)
Clancy, Rudy, 2001: Cellular consequences of HERG mutations in the long QT syndrome: precursors to sudden cardiac death (IKrT474I Mutant Epicardial Cell)
Clancy, Rudy, 2001: Cellular consequences of HERG mutations in the long QT syndrome: precursors to sudden cardiac death (IKrT474I Mutant Midmyocardial Cell)
Clancy, Rudy, 2001: Cellular consequences of HERG mutations in the long QT syndrome: precursors to sudden cardiac death (INaKPQ Mutant Epicardial Cell)
Clancy, Rudy, 2001: Cellular consequences of HERG mutations in the long QT syndrome: precursors to sudden cardiac death (Wild Type Midmyocardial Cell)
Clancy, Rudy, 2002: Na Channel Mutation That Causes Both Brugada Syndrome and Long-QT Syndrome Phenotypes: A Simulation Study of Mechanism (Wild Type Epicardial Cell)
Clancy, Rudy, 2002: Na Channel Mutation That Causes Both Brugada Syndrome and Long-QT Syndrome Phenotypes: A Simulation Study of Mechanism (INa1795insD Mutant Endocardial Cell)
Clancy, Rudy, 2002: Na Channel Mutation That Causes Both Brugada Syndrome and Long-QT Syndrome Phenotypes: A Simulation Study of Mechanism (INa1795insD Mutant Epicardial Cell)
Clancy, Rudy, 2002: Na Channel Mutation That Causes Both Brugada Syndrome and Long-QT Syndrome Phenotypes: A Simulation Study of Mechanism (INa1795insD Mutant Midmyocardial Cell)
Clancy, Rudy, 2002: Na Channel Mutation That Causes Both Brugada Syndrome and Long-QT Syndrome Phenotypes: A Simulation Study of Mechanism (Wild Type Endocardial Cell)
Clancy, Rudy, 2002: Na Channel Mutation That Causes Both Brugada Syndrome and Long-QT Syndrome Phenotypes: A Simulation Study of Mechanism (Wild Type Midmyocardial Cell)
Colegrove, Albrecht, Friel, 2000: Quantitive Analysis of Mitochondrial Ca2+ Uptake and Release Pathways in Sympathetic Neurons Reconstruction of the Recovery after Depolarisation-evoked [Ca2+] Elevations
Corrias, Buist, 2007: corrias_buist_2007.cellml
Corrias, Buist, 2008: Quantitative cellular description of gastric slow wave activity
Cortassa, Aon, Marban, Winslow, O'Rourke, 2003: An Integrated Model of Cardiac Mitrochondrial Energy Metabolism and Calcium Dynamics
Courtemanche, Ramirez, Nattel, 1998: Ionic mechanisms underlying human atrial action potential properties: insights from a mathematical model
Cui, Kaandorp, Lloyd, 2008: Model does not include the zinc-buffering effects of TPEN
Cui, Kaandorp, Lloyd, 2008: Model includes the zinc-buffering effects of TPEN
David, Cumin, Phd, Model: FINAL.cellml
Davies, Mistry, Hussein, Pollard, Valentin, Swinton, Abi-Gerges, 2012: An in silico canine cardiac midmyocardial action potential duration model as a tool for early drug safety assessment
De Vries, Sherman, 2000: Channel Sharing in Pancreatic Beta-Cells Revisited: Enhancement of Emergent Bursting by Noise
De Vries, Sherman, 2001: From Spikers to Bursters Via Coupling: Help from Heterogeneity
De Young, Keizer, 1992: A single-pool inositol 1,4,5-triphosphate-receptor-based model for agonist-stimulated oscillations in Ca 2+ concentration
Decker, Heijman, Silva, Hund, Rudy, 2009: Properties and ionic mechanisms of action potential adaptation, restitution, and accommodation in canine epicardium
Demir, Clark, Giles, 1999: Parasympathetic modulation of sinoatrial node pacemaker activity in rabbit heart: a unifying model
Demir, Clark, Giles, Murphey, 1994: A Mathematical Model of a Rabbit Sinoatrial Node Cell
DiFrancesco, Noble, 1985: A Model of Cardiac Electrical Activity Incorporating Ionic Pumps and Concentration Changes
Dokos, Celler, Lovell, 1996: Ion currents underlying sinoatrial node pacemaker activity: a new single cell mathematical model
Drouhard, Roberge, 1987: Revised formulation of the Hodgkin-Huxley representation of the sodium current in cardiac cells
Dumaine, Towbin, Brugada, Vatta, Nesterenko, Nesterenko, Brugada, Brugada, Antzelevitch, 1999: Ionic mechanisms responsible for the electrocardiographic phenotype of the Brugada Syndrome are temperature dependent
Earm, Noble, 1990: A Model of the Single Atrial Cell: Relation between Calcium Current and Calcium Release
Ebihara, Johnson, 1980: Fast sodium current in cardiac muscle: A quantitative description
Endresen, 1996: Chaos in Weakly-coupled Pacemaker Cells
Espinosa, 1998: L'Echange Na+/Ca2+ dans l'Hypertrophie Ventriculaire D'Altitude chez le Rat: Etude Electrophysiologique et Utilisation du Modele "Oxsoft Heart": normal heart cell model
Espinosa, 1998: L'Echange Na+/Ca2+ dans l'Hypertrophie Ventriculaire D'Altitude chez le Rat: Etude Electrophysiologique et Utilisation du Modele "Oxsoft Heart": hypertrophic heart cell model
Faber, Rudy, 2000: Action potential and contractility changes in [Na(+)](i) overloaded cardiac myocytes: a simulation study (Original model in steady state)
Faber, Rudy, 2000: Action potential and contractility changes in [Na(+)](i) overloaded cardiac myocytes: a simulation study (Updated model with an added Ito current and and updated Irel current)
Fall, Keizer, 2001: Mitochondrial Modulation of Intracellular Ca2+ Signalling
Favile, Pullan, Sanders, Koh, Lloyd, Smith, 2009: Biophysically based mathematical modeling of interstitial cells of Cajal slow wave activity generated from a discrete unitary potential basis
Faville, Pullan, Sanders, Smith, 2008: A Biophysically Based Mathematical Model of Unitary Potential Activity in Interstitial Cells of Cajal
Fenton, Karma, 1998: Vortex dynamics in three-dimensional continuous myocardium with fiber rotation: Filament instability and fibrillation (BR Model)
Fenton, Karma, 1998: Vortex dynamics in three-dimensional continuous myocardium with fiber rotation: Filament instability and fibrillation (GP Model)
Fenton, Karma, 1998: Vortex dynamics in three-dimensional continuous myocardium with fiber rotation: Filament instability and fibrillation (MBR Model)
Fenton, Karma, 1998: Vortex dynamics in three-dimensional continuous myocardium with fiber rotation: Filament instability and fibrillation (MLR-1 Model)
Fink, Noble, Virag, Varro, Giles, 2008: Contributions of HERG K+ current to repolarization of the human ventricular action potential
Fitzhugh, 1961: Impulses and Physiological States in Theoretical Models of Nerve Membrane
Fohlmeister, Miller, 1997: Impulse Encoding Mechanisms of Ganglion Cells in the Tiger Salamander Retina
Fox, McHarg, Gilmour, 2002: Ionic mechanism of electrical alternans
Francis, Garcia, Middleton, 2012: A model for pacemaking in substantia nigra neurons (A simple model based on a spherical geometry)
Francis, Garcia, Middleton, 2013: A single compartment model of pacemaking in dissasociated Substantia nigra neurons with hyperbolic tetrahedral geometry
Fridlyand, Tamarina, Philipson, 2003: Modeling of Ca2+ flux in pancreatic beta-cells: role of the plasma membrane and intracellular stores
Friel, 1995: [Ca2+]i oscillations in sympathetic neurons: an experimental test of a theoretical model
Gall, Susa, 1999: Effect of Na/Ca Exchange on Plateau Fraction and [Ca]i in Models for Bursting in Pancreatic Beta-Cells (Model A)
Gall, Susa, 1999: Effect of Na/Ca Exchange on Plateau Fraction and [Ca]i in Models for Bursting in Pancreatic Beta-Cells (Model B)
Gall, Susa, 1999: Effect of Na/Ca Exchange on Plateau Fraction and [Ca]i in Models for Bursting in Pancreatic Beta-Cells (Model C)
Garny, Kohl, Hunter, Boyett, Noble, 2003: One-dimensional Rabbit Sinoatrial Node Models: Benefits and Limitations
Goforth, Bertram, Khan, Zhang, Sherman, Satin, 2002: Calcium-activated K+ Channels of Mouse Beta Cells are Controlled by Both Store and Cytoplasmic Ca2+: Experimental and Theoretical Studies
Grandi, Pasqualini, Bers, 2009: A novel computational model of the human ventricular action potential and Ca transient
Greenstein, Wu, Po, Tomaselli, Winslow, 2000: Role of the Calcium-Independent Transient Outward Current Ito1 in Shaping Action Potential Morphology and Duration
Hilgemann, Noble, 1987: Excitation-contraction coupling and extracellular calcium transients in rabbit atrium: reconstruction of basic cellular mechanisms
Hinch, Greenstein, Tanskanen, Xu, Winslow, 2004: A Simplified Local Control Model of Calcium-Induced Calcium Release in Cardiac Ventricular Myocytes
Hodgkin, Huxley, 1952: A quantitative description of membrane current and its application to conduction and excitation in nerve (Original Model + Stimulus)
Hodgkin, Huxley, 1952: A quantitative description of membrane current and its application to conduction and excitation in nerve (Original Model)
Hund, Rudy, 2004: Rate dependence and regulation of action potential and calcium transient in a canine cardiac ventricular cell model (Basic Model)
Hund, Rudy, 2004: Rate dependence and regulation of action potential and calcium transient in a canine cardiac ventricular cell model (Tissue Model)
Hunter, McCulloch, ter Keurs, 1998: Modelling the mechanical properties of cardiac muscle
Hunter, McNaughton, Noble, 1975: Analytical models of propagation in excitable cells
Inada, Hancox, Zhang, Boyett, 2009: One-dimensional mathematical model of the atrioventricular node including atrio-nodal, nodal, and nodal-his cells (Atrio-Nodal Cell)
Inada, Hancox, Zhang, Boyett, 2009: One-dimensional mathematical model of the atrioventricular node including atrio-nodal, nodal, and nodal-his cells (Nodal-His Cell)
Inada, Hancox, Zhang, Boyett, 2009: One-dimensional mathematical model of the atrioventricular node including atrio-nodal, nodal, and nodal-his cells (Nodal Cell)
Iribe, Kohl, Noble, 2006: Modulatory effect of calmodulin-dependent kinase II (CaMKII) on sarcoplasmic reticulum Ca2+ handling and interval-force relations: a modelling study.
Iyer, Hajjar, Armoundas, 2007: Mechanisms of Abnormal Calcium Homeostasis in Mutations Responsible for Catecholaminergic Polymorphic Ventricular Tachycardia
Iyer, Mazhari, Winslow, 2004: A computational model of the human left-ventricular epicardial myocyte
Jafri, Rice, Winslow, 1998: Cardiac Ca2+ Dynamics: The Roles of Ryanodine Receptor Adaptation and Sarcoplasmic Reticulum Load
Jafri, Rice, Winslow, 1998: Cardiac Ca2+ Dynamics: The Roles of Ryanodine Receptor Adaptation and Sarcoplasmic Reticulum Load (Extended Model)
Katsnelson, Nikitina, Chemla, Solovyova, Coirault, Lecarpentier, Markhasin, 2004: Time is expressed in milliseconds, calcium variables and parameters are normalised to total TnC concentration.
Katsnelson, Nikitina, Chemla, Solovyova, Coirault, Lecarpentier, Markhasin, 2004: Time is expressed in seconds, calcium variables and parameters are expressed in absolute values.
Katsnelson, Nikitina, Chemla, Solovyova, Coirault, Lecarpentier, Markhasin, 2004: Time is expressed in seconds, calcium variables and parameters are normalised to total TnC concentration.
Keizer, Levine, 1996: Ryanodine Receptor Adaptation and Ca2+-Induced Ca2+ Release-Dependent Ca2+ Oscillations
Kneller, Ramirez, Chartier, Courtemanche, Nattel, 2002: Time-dependent transients in an ionically based mathematical model of the canine atrial action potential
Kurata, Hisatome, Imanishi, Shibamoto, 2002: Dynamical description of sinoatrial node pacemaking: improved mathematical model for primary pacemaker cell
Land, Niederer, Aronsen, Espe, Zhang, Louch, Sjaastad, Sejersted, Smith, 2012: An analysis of deformation-dependent electromechanical coupling in the mouse heart
Landesberg, Sideman, 1994: Mechanical regulation of cardiac muscle by coupling calcium kinetics with cross-bridge cycling: a dynamic model
LeBeau, Robson, McKinnon, Donald, Sneyd, 1997: Generation of Action Potentials in a Mathematical Model of Corticotrophs
Li, Bertram, Rinzel, 1996: Modeling N-methyl-D-aspartate-induced bursting in dopamine neurons (simple model based on the equations in the published paper)
Li, Bertram, Rinzel, 1996: Modeling N-methyl-D-aspartate-induced bursting in dopamine neurons (complex model based on the equations in the published paper)
Li, Bertram, Rinzel, 1996: Modeling N-methyl-D-aspartate-induced bursting in dopamine neurons (simple model based on the equations in the original code)
Li, Rinzel, 1994: Equations for InsP3 Receptor-mediated [Ca2+]i Oscillations Derived from a Detailed Kinetic Model: A Hodgkin-Huxley Like Formalism
Li, Smith, 2009: Li_Smith_2009_C57BL7_WT.cellml
Lindblad, Murphey, Clark, Giles, 1996: A Model of the Action Potential and Underlying Membrane Currents in a Rabbit Atrial Cell
Livshitz, Rudy, 2007: Regulation of Ca2+ and electrical alternans in cardiac myocytes: role of CAMKII and repolarizing currents
Lovell, Cloherty, Celler, Dokos, 2004: A gradient model of cardiac pacemaker myocytes
Luo, Rudy, 1991: A Model of the Ventricular Cardiac Action Potential. Depolarization, repolarization and their interaction
Luo, Rudy, 1994: A Dynamic Model of the Cardiac Ventricular Action Potential I. Simulations of Ionic Currents and Concentration Changes
Luo, Rudy, 1994: A Dynamic Model of the Cardiac Ventricular Action Potential I. Simulations of Ionic Currents and Concentration Changes
Magnus, Keizer, 1997: Minimal Model of beta-cell mitochondrial Ca2+ handling
Magnus, Keizer, 1998: Model of beta_cell mitochondrial calcium handling and electrical activity. I. Cytoplasmic variables
Mahajan, Karma, Garfinkel, Qu, Weiss, Shiferaw, Sato, Baher, Olcese, Xie, Yang, Chen, Restrepo, 2008: A rabbit ventricular action potential model replicating cardiac dynamics at rapid heart rates
Maleckar, Greenstein, Trayanova, Giles, 2009: Mathematical simulations of ligand-gated and cell-type specific effects on the action potential of human atrium
Maltsev, Lakatta, 2009: Non-steady state model translated from the published paper
Maltsev, Lakatta, 2009: Steady state model adapted from the author's orignal code
Marhl, Haberichter, Brumen, Heinrich, 2000: Complex calcium oscillations and the role of mitochondria and cytosolic proteins
Marhl, Schuster, Brumen, Heinrich, 1997: Modelling the interrelations between calcium oscillations and ER membrane potential oscillations
Matsuoka, Sarai, Kuratomi, Ono, Noma, 2003: Role of individual ionic current systems in ventricular cells hypothesized by a model study
Mazhari, Greenstein, Winslow, Marban, Nuss, 2001: Molecular Interactions Between Two Long-QT Syndrome Gene Products, HERG and KCNE2, Rationalized by In Vitro and In Silico Analysis
McAllister, Noble, Tsien, 1975: Reconstruction of the electrical activity of cardiac Purkinje fibres (Model B)
McAllister, Noble, Tsien, 1975: Reconstruction of the electrical activity of cardiac Purkinje fibres (Model A)
Mears, Sheppard, Atwater, Rojas, Bertram, Sherman, 1997: Evidence That Calcium Release-activated Current Mediates the Biphasic Electrical Activity of Mouse Pancreatic Beta-Cells
Michailova, McCulloch, 2001: Model study of ATP and ADP buffering, transport of Ca2+ and Mg2+, and regulation of ion pumps in ventricular myocyte
Michailova, Saucerman, Belik, McCulloch, 2005: Modeling regulation of cardiac KATP and L-type Ca2+ currents by ATP, ADP, and Mg2+
Miftakhov, Abdusheva, Christensen, 1999: Numerical Simulation of Motility Patterns of the Small Bowel. I. Formulation of a Mathematical Model
Mikane, Suga, Araki, Kohno, Nakayama, Suzuki, Shimuzi, Matsubara, Hirakawa, Takaki, 1997: Mechanism of Constant Contractile Efficiency Under Cooling Intropy of Myocardium: Simulation
Mitchell, Schaeffer, 2003: A two-current model for the dynamics of cardiac membrane
Mlcek, Neumann, Kittnar, Novak, 2001: Mathematical Model of the Electromechanical Heart Contractile System - Regulatory Subsystem Physiological Considerations
Morris, Lecar, 1981: Voltage oscillations in the barnacle giant muscle fiber: reduced model
Morris, Lecar, 1981: Voltage oscillations in the barnacle giant muscle fiber: complete model
Mosekilde, Lading, Yanchuk, Maistrenko, 2001: Bifurcation structure of a model of bursting pancreatic cells
Nash, Panfilov, 2004: Electromechanical model of excitable tissue to study reentrant cardiac arrhythmias
Niederer, Hunter, Smith, 2006: A quantitative analysis of cardiac myocyte relaxation: a simulation study
Niederer, Smith, 2007: A Mathematical Model of the Slow Force Response to Stretch in Rat Ventricular Myocytes
Noble, 1962: A Modification of the Hodgkin-Huxley Equations Applicable to Purkinje Fibre Action and Pace-Maker Potentials
Noble, DiFrancesco, Denyer, 1989: Ionic Mechanisms in Normal and Abnormal Cardiac Pacemaker Activity
Noble, Noble, 1984: A Model of Sino-Atrial Node Electrical Activity Based on a Modification of the DiFrancesco-Noble (1984) Equations
Noble, Noble, 2001: Remodelling of Calcium Dynamics in Guinea-Pig Ventricular Cells
Noble, Noble, Bett, Earm, Ho, So, 1991: The Role of Sodium-Calcium Exchange During the Cardiac Action Potential
Noble, Varghese, Kohl, Noble, 1998: Improved guinea-pig ventricular cell model incorporating a diadic space, IKr and IKs, and length- and tension-dependent processes (Basic Model)
Noble, Varghese, Kohl, Noble, 1998: Improved guinea-pig ventricular cell model incorporating a diadic space, IKr and IKs, and length- and tension-dependent processes (Extended Model)
Noble, Varghese, Kohl, Noble, 1998: Improved guinea-pig ventricular cell model incorporating a diadic space, IKr and IKs, and length- and tension-dependent processes (Stretch Model)
Noble, Varghese, Kohl, Noble, 1998: Model A: single stimulus
Noble, Varghese, Kohl, Noble, 1998: Model B: multiple stimuli
Nygren, Fiset, Firek, Clark, Lindblad, Clark, Giles, 1998: Mathematical Model of an Adult Human Atrial Cell: The Role of K+ Currents in Repolarization
Ostby, Omholt, Oyehaug, Einevoll, Nagelhus, Plahte, Zeuthen, Voipio, Lloyd, Ottersen, 2008: Astrocytic processes explaining neural-activity-induced shrinkage of extraneuronal space
Oyehaug, Ostby, Lloyd, Omholt, Einevoll, 2011: Dependence of spontaneous neuronal firing and depolarization block on astroglial membrane processes: Fig 2A
Oyehaug, Ostby, Lloyd, Omholt, Einevoll, 2011: Dependence of spontaneous neuronal firing and depolarization block on astroglial membrane processes: Fig 2B
Oyehaug, Ostby, Lloyd, Omholt, Einevoll, 2011: Dependence of spontaneous neuronal firing and depolarization block on astroglial membrane processes: Fig 2A
Oyehaug, Ostby, Lloyd, Omholt, Einevoll, 2011: Dependence of spontaneous neuronal firing and depolarization block on astroglial membrane processes: Fig 2B
Pandit, Clark, Giles, Demir, 2001: Rat ventricular myocyte model from the original Pandit 2001 paper: epicardial cell
Pandit, Clark, Giles, Demir, 2001: Rat ventricular myocyte model from the original Pandit 2001 paper: endocardial cell
Pandit, Clark, Giles, Demir, 2001: Rat ventricular myocyte model modified to simulate conditions in type-I diabetes
Pandit, Giles, Demir, 2003: A Mathematical Model of the Electrophysiological Alterations in Rat Ventricular Myocytes in Type-I Diabetes
Pandit, Giles, Demir, 2003: Mouse ventricular myocyte model
Pasek, Simurda, Christe, 2006: CellML 1.0 version of the model which stabilises at 1Hz
Pasek, Simurda, Christe, 2006: CellML 1.0 version of the model which stabilises at 5Hz
Pasek, Simurda, Christe, 2006: CellML 1.1 version of the model
Pasek, Simurda, Orchard, Christe, 2008: A model of the guinea-pig ventricular cardiac myocyte incorporating a transverse-axial tubular system
Plant, 1981: Bifurcation and resonance in a model for bursting nerve cells
Poh, Corrias, Cheng, Buist, 2012: A Quantitative Model of Human Jejunal Smooth Muscle Cell Electrophysiology
Priebe, Beuckelmann, 1998: Simulation Study of Cellular Electrical Properties in Heart Failure
Puglisi, Bers, 2001: LabHEART: an interactive computer model of rabbit ventricular myocyte ion channels and Ca transport
Purvis, Butera, 2005: Ionic Current Model of a Hypoglossal Motoneuron
Purvis, Smith, Koizumi, Butera, 2007: Intrinsic Bursters Increase the Robustness of Rythm Generation in an Excitatory Network: Single Pacemaker Cell
Purvis, Smith, Koizumi, Butera, 2007: Intrinsic Bursters Increase the Robustness of Rythm Generation in an Excitatory Network: Single Non-Pacemaker Cell
Ramirez, Nattel, Courtemanche, 2000: Mathematical analysis of canine atrial action potentials: rate, regional factors, and electrical remodeling
Razumova, Bukatina, Campbell, 1999: Stiffness-distortion sacromere model for muscle stimulation
Reidl, Borowski, Sensse, Starke, Zapotocky, Eiswirth, 2006: Model of Calcium Oscillations Due to Negative Feedback in Olfactory Cilia
Rice, Jafri, Winslow, 2000: Modeling short-term interval-force relations in cardiac muscle
Rice, Winslow, Hunter, 1999: Comparison of putative cooperative mechanisms in cardiac muscle: length dependence and dynamic responses (model 1)
Rice, Winslow, Hunter, 1999: Comparison of putative cooperative mechanisms in cardiac muscle: length dependence and dynamic responses (model 2)
Rice, Winslow, Hunter, 1999: Comparison of putative cooperative mechanisms in cardiac muscle: length dependence and dynamic responses (model 3)
Rice, Winslow, Hunter, 1999: Comparison of putative cooperative mechanisms in cardiac muscle: length dependence and dynamic responses (model 4)
Rice, Winslow, Hunter, 1999: Comparison of putative cooperative mechanisms in cardiac muscle: length dependence and dynamic responses (model 5)
Rice, Winslow, Jafri, 1999: Modeling Gain and Gradedness of Ca2+ Release in the Functional Unit of the Cardiac Diadic Space

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