Block of single cardiac Na+ channels by antiarrhythmic drugs: The effect of amiodarone, propafenone and diprafenone

Kohlhardt, M.; Fichtner, H.

doi:10.1007/bf01870449

Cited by 60 publications

(33 citation statements)

References 38 publications

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“…This already has been proven in normal cardiac Na + channels with intact inactivation 5 and was further stressed by the present experiments with modified channels. In the presence of 20 /imol/1 propafenone, their unitary conductance was found to be 12 pS in two patches.…”

Section: Do Unblocked Dpi-modified Na + Channels Conduct Normally?supporting

confidence: 76%

“…5 Blockade prevents the Na + channel from attaining the conducting configuration while unblocked Na + channels show apparently normal elementary properties, including unitary current size and open-state kinetics. This also implies that plugging and unplugging, the steps that initiate and terminate the channel blockade, remain undetectable even in singlechannel studies.…”

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confidence: 99%

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On the mechanism of drug-induced blockade of Na+ currents: interaction of antiarrhythmic compounds with DPI-modified single cardiac Na+ channels.

Kohlhardt

Fichtner

Fröbe

et al. 1989

Circulation Research

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In patch-clamped membranes from neonatal rat cardiocytes, elementary Na + currents were recorded at 19° C for study of the inhibitory influence of several antiarrhythmic drugs including lidocaine, diprafenone, propafenone, and prajmalium on DPI-modified cardiac Na L ocal anesthetics and related antiarrhythmic drugs compose a structurally heterogeneous group of organic compounds capable of interacting with Na + channels in excitable membranes, including cardiac cells. Several lines of evidence strongly support the assumption that a channel-associated binding site exists 1 -3 whose interaction or binding with these drugs will finally block the channel and hinder sodium ions from passing through the pore. The resultant decrease in excitability may be an antiarrhythmic principle in heart From the Physiological Institute of the University Freiburg Freiburg/Br., Federal Republic of Germany.Supported by a grant of the Deutsche Forschungsgemeinschaft (Ko 778/2-1), Bonn, Federal Republic of Germany.Address for correspondence: Professor Dr. M. Kohlhardt, Physiological Institute of the University, Hermann-Herder-Str. 7, D-78 Freiburg/Br., Federal Republic of Germany.Received January 20, 1988; accepted September 28, 1988. to suppress irregular impulses. The remarkably different manifestation of Na + current depression, which attracted considerable theoretical interest and was well documented in numerous biophysical studies during the past years, reflects the combined influence of such factors as voltage, driving rate, and drug hydrophobicity in determination of the strength of blockade of Na + currents. The rather complex block phenomenology finds elegant and conclusive explanations by the models of Hille 2 and Hondeghem and Katzung 3 on the one hand and Starmer et al< on the other hand. The HilleHondeghem-Katzung model postulates a modulated receptor whose drug affinity depends on the channel state, rested or activated/inactivated, while the Starmer model assumes a guarded receptor, that is, drug access is controlled by the channel state. Such modeling of block proved valuable and indispensable in the understanding of some elementary properties of voltage-dependent Na + channels.by guest on May 12, 2018

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Section: Do Unblocked Dpi-modified Na + Channels Conduct Normally?supporting

confidence: 76%

mentioning

confidence: 99%

On the mechanism of drug-induced blockade of Na+ currents: interaction of antiarrhythmic compounds with DPI-modified single cardiac Na+ channels.

Kohlhardt

Fichtner

Fröbe

et al. 1989

Circulation Research

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“…The effect on the kinetics of I Na inactivation was unex- pected given the known actions of amiodarone, which either does not change the kinetics of fast inactivation (Follmer et al, 1987;Kohlhardt and Fichtner, 1988) or accelerates the decay of late currents (Maltsev et al, 2001). It resembles that of many drugs, including animal or plant toxins, that interact with specific sites on the voltage-dependent Na ϩ channel and modify inactivation (Narahashi, 1996;Catterall, 2000;Goldin, 2001).…”

Section: Discussionmentioning

confidence: 99%

“…In the present study, we report marked acute effects of KB on the inactivation of Na ϩ channels. These effects were unexpected based on those known for amiodarone (Follmer et al, 1987;Kohlhardt and Fichtner, 1988;Kodama et al, 1999;Maltsev et al, 2001), but a few studies have reported similar effects with high concentrations of thyroid hormones (Craelius et al, 1990;Harris et al, 1991;Dudley and Baumgarten, 1993).…”

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confidence: 90%

Slowing of the Inactivation of Cardiac Voltage-Dependent Sodium Channels by the Amiodarone Derivative 2-Methyl-3-(3,5-diiodo-4-carboxymethoxybenzyl)benzofuran (KB130015)

Mačianskienė

Viappiani²,

Sipido³

et al. 2003

J Pharmacol Exp Ther

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2-Methyl-3-(3,5-diiodo-4-carboxymethoxybenzyl)benzofuran (KB130015 or KB) is a new drug, structurally related to amiodarone and to thyroid hormones. Its effects on cardiac voltagedependent Na ϩ current (I Na ) were studied in pig single ventricular myocytes at 22°C using the whole-cell (with [Na ϩ ] i ϭ [Na ϩ ] o ϭ 10 mM) and cell-attached patch-clamp techniques. KB markedly slowed I Na inactivation, due to the development of a slow-inactivating component ( slow Ϸ 50 ms) at the expense of the normal, fast-inactivating component ( fast Ϸ 2-3 ms). The effect was concentration-dependent, with a half-maximally effective concentration (K 0.5 ) of 2.1 M. KB also slowed the recovery from inactivation and shifted the voltage-dependent inactivation (⌬V 0.5 ϭ Ϫ15 mV; K 0.5 Ն 6.9 M) and activation to more negative potentials. Intracellular cell dialysis with 10 M KB had marginal or no effect on inactivation and did not prevent the effect of extracellularly applied drug. In cell-attached patches, extracellular KB prolonged Na ϩ channel opening. Amiodarone (10 M) and 10 M 3,5,-diiodo-L-thyropropionic acid had no effect on inactivation and did not prevent KB effects. 3,3Ј,5-Triodo-L-thyronine (T 3 ) also had no effect on inactivation, but at 10 M it increased I Na amplitude and partially prevented the slowing of inactivation by KB. These data suggest the existence of a binding site for KB and T 3 on Na ϩ channels.Voltage-dependent Na ϩ channels play an important role in the initiation and conduction of electrical signals in excitable cells. A dysfunction of Na ϩ channels, as may occur after genetic mutation or as a consequence of drug action, is the basis for a variety of cardiac arrhythmias (e.g., those related to the long QT and the Brugada syndromes), skeletal muscle diseases, and epileptic seizures (for reviews, see Fozzard and

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“…We cannot rule out other possible mechanisms for the different voltage-dependence of the use-dependent sodium channel inhibition with diprafenone and propafenone. For instance, Kohlhardt & Fichtner (1988b) have demonstrated in their cell-attached patch clamp experiments recording single Na' channel currents that diprafenone, unlike propafenone, shortens the lifetime of unblocked channels as an additional effect, apart from its blocking action. Such modification is expected to have a complex influence on the effects of the drug on the net sodium inward current and Vmax of action potential.…”

Section: Discussionmentioning

confidence: 99%

Electrophysiological effects of diprafenone, a dimethyl congener of propafenone on guinea‐pig ventricular cells

Kodama

Suzuki

Honjo

et al. 1992

British J Pharmacology

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Block of single cardiac Na+ channels by antiarrhythmic drugs: The effect of amiodarone, propafenone and diprafenone

Cited by 60 publications

References 38 publications

On the mechanism of drug-induced blockade of Na+ currents: interaction of antiarrhythmic compounds with DPI-modified single cardiac Na+ channels.

On the mechanism of drug-induced blockade of Na+ currents: interaction of antiarrhythmic compounds with DPI-modified single cardiac Na+ channels.

Slowing of the Inactivation of Cardiac Voltage-Dependent Sodium Channels by the Amiodarone Derivative 2-Methyl-3-(3,5-diiodo-4-carboxymethoxybenzyl)benzofuran (KB130015)

Electrophysiological effects of diprafenone, a dimethyl congener of propafenone on guinea‐pig ventricular cells

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