Voltage clamp experiments on ventricular myocardial fibres
G. W. Beeler,H. Reuter +1 more
TLDR
A voltage clamp method utilizing a sucrose gap and glass microelectrodes was developed and used to study dog ventricular myocardial fibre bundles and the limitations and the reliability are demonstrated.Abstract:
1. A voltage clamp method utilizing a sucrose gap and glass microelectrodes was developed and used to study dog ventricular myocardial fibre bundles. The limitations and the reliability of this method are demonstrated by a series of tests.
2. A dynamic sodium current, excited at membrane potentials more positive than −65 mV, was measured. The equilibrium potential for this large, rapid inward current depends directly on [Na]o, shifting 29·0 ± 2·3 mV (± S.E. of mean), as opposed to a theoretically expected value of 30·6 mV, when [Na]o is reduced to 31% of normal.
3. Sodium current is inactivated by conditioning depolarizations. Complete inactivation occurs with conditioning potentials more positive than −45 mV, and 50% inactivation occurs at about −55 mV. The location of the inactivation curve shifts along the voltage axis, when [Ca]o is varied between 0·2 and 7·2 m M.
4. A second, much smaller and slower net inward current, with a threshold around −30 mV, and an equilibrium potential above +40 mV was also observed.
5. The ‘steady-state’ current—voltage relationship (after 300–600 msec) exhibits inward-going (anomalous) rectification with negative slope between −50 and −25 mV.
6. A small, very slowly developing component of outward current was observed at inside positive potentials. The equilibrium potential for this current, although slightly dependent on [K]o, is neither identical with the potassium equilibrium potential nor with the resting potential in normal Tyrode solution.
7. Anatomical limitations, primarily resistance in the extracellular space within the bundle, prevent complete characterization of the rapid, large sodium current, but do not limit the application of the clamp method to the study of other, smaller and slower currents. The evidence for this is discussed extensively in the Appendix.read more
Citations
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Reconstruction of the action potential of ventricular myocardial fibres
G. W. Beeler,H. Reuter +1 more
TL;DR: A mathematical model of membrane action potentials of mammalian ventricular myocardial fibres is described, based as closely as possible on ionic currents which have been measured by the voltage‐clamp method.
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Inwardly Rectifying Potassium Channels: Their Structure, Function, and Physiological Roles
Hiroshi Hibino,Atsushi Inanobe,Kazuharu Furutani,Shingo Murakami,Ian Findlay,Yoshihisa Kurachi +5 more
TL;DR: The crystal structure of different Kir channels is opening the way to understanding the structure-function relationships of this simple but diverse ion channel family.
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Time- and voltage-dependent interactions of antiarrhythmic drugs with cardiac sodium channels.
TL;DR: A molecular model on the action of local anesthetic-like antiarrhytmic drugs is formulated: the drugs can interact with the sodium channels in the rested, activated and inactivated states, and each of these interactions is characterized by an association and dissociation rate constant.
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A Model of Cardiac Electrical Activity Incorporating Ionic Pumps and Concentration Changes
Dario DiFrancesco,Denis Noble +1 more
TL;DR: The model takes account of extensive developments in experimental work since the formulation of the M.N. Noble equations, and successfully account for all the properties formerly attributed to i $\_{K2}$ , as well as giving more complete descriptions of i $\_K$ and i $\-K$ .
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Reconstruction of the electrical activity of cardiac Purkinje fibres.
TL;DR: The electrical activity of Cardiac Purkinje fibres was reconstructed using a mathematical model of the membrane current and the individual components of ionic curent were described by equations based as closely as possible on previous experiments using the voltage clamp technique.
References
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A. L. Hodgkin,A. F. Huxley +1 more
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A. L. Hodgkin,A. F. Huxley +1 more
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Measurement of current-voltage relations in the membrane of the giant axon of Loligo.
TL;DR: The importance of ionic movements in excitable tissues has been emphasized by a number of recent experiments which are consistent with the theory that nervous conduction depends on a specific increase in permeability which allows sodium ions to move from the more concentrated solution outside a nerve fibre to the more dilute solution inside it.
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The dual effect of membrane potential on sodium conductance in the giant axon of Loligo
A. L. Hodgkin,A. F. Huxley +1 more
TL;DR: This paper contains a further account of the electrical properties of the giant axon of Loligo and deals with the 'inactivation' process which gradually reduces sodium permeability after it has undergone the initial rise associated with depolarization.
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