Analysis of the ionic basis for cocaine's biphasic effect on action potential duration in guinea-pig ventricular myocytes.

The effects of cocaine on the duration of the cardiac action potential were investigated in isolated guinea-pig ventricular myocytes at 37 degrees C. Following a 10-min exposure of cells to 3 microM cocaine, APD90 increased significantly by +22 +/- 5% (n = 6). In contrast, following a ten minute exposure to 30 or 100 microM cocaine, APD90 was reduced by -24 +/- 6% (n = 5) and -53 +/- 2% (n = 8), respectively. The ionic basis for cocaine's effects on the APD was investigated using the whole cell voltage-clamp technique at 37 degrees C. Cocaine produced a concentration-dependent reduction in the amplitude of IK tail currents with an estimated IC50 of 4 microM. The kinetics and voltage dependence of the cocaine-sensitive current indicate that cocaine selectively blocks a current identical to the E-4031 sensitive current IKr. No significant reduction of the slow component of IK (IKs) was observed during exposure to 30 or 100 microM cocaine. High (30 and 100 microM) concentrations of cocaine also produced a significant reduction of both the L-type calcium current and the TTX-sensitive plateau current. Pre-treatment of cells with 10 microM TTX also converted the APD-shortening effect of 30 microM cocaine to one of APD-prolonging. This implies that cocaine block of a TTX-sensitive window current contributes to the APD-shortening effects produced by high concentrations of cocaine. We conclude that: (1) cocaine produces a biphasic concentration-dependent effect on repolarization in guinea-pig ventricular myocytes; and (2) this biphasic effect on repolarization results from differences in the sensitivity of inward and outward currents to the blocking effects of cocaine.

Differential block of cardiac delayed rectifier current by class Ic antiarrhythmic drugs: evidence for open channel block and unblock.

OBJECTIVE: The aim was to compare the effects of the class Ic antiarrhythmic drugs flecainide, encainide, and recainam on the delayed rectifier current, IK. METHODS: Membrane currents were studied using the single suction pipette voltage clamp technique in freshly dissociated cat ventricular myocytes bathed in HEPES buffered physiological saline at 32 degrees C. RESULTS: Flecainide and encainide decreased IK with IC50 values of 2.1 microM and 6 microM, respectively. Recainam (100 microM) reduced IK by only 7 (SEM 3)% after 20-30 min exposure and by 19% after an 80 min exposure (IC50 > 400 microM). None of the compounds blocked the inward rectifier, IK1. Block of IK by flecainide and encainide increased with depolarisation following a voltage dependence similar to that describing channel activation. Flecainide and encainide also slowed the time course of the IK tail currents, consistent with drug dissociating from open channels. CONCLUSIONS: The observed voltage dependence for IK block by flecainide and encainide resembles the interaction reported between these agents and the excitatory sodium channel, ie, depolarisation enhances block while repolarisation leads to removal of block. The results further suggest that the electrophysiological profile of class Ic agents can have a markedly different ionic basis, ie, K+ channel block by flecainide and encainide is balanced by a potent block of sodium channels, while recainam appears to be a weak but relatively specific blocker of sodium channels only. These differences are not readily accommodated by the current Harrison-Vaughan-Williams classification scheme, and suggest the possibility that potentially important drug specific differences can exist within the same antiarrhythmic drug class.

Effect of ambasilide, a new class III agent, on plateau currents in isolated guinea pig ventricular myocytes: block of delayed outward potassium current.

The actions of ambasilide (LU-47110) on the action potential and membrane currents of isolated guinea pig ventricular myocytes were studied using voltage clamp techniques. Ambasilide (1 microM) prolonged the action potential (APD) at 20, 50 and 90% repolarization by 11.2 +/- 4.3, 13.8 +/- 3.9 and 13.6 +/- 3.7%, respectively, compared to control (n = 10). APD prolongation was attributed to the block of delayed rectifier outward current (Ik) in a concentration-dependent fashion (0.01-10 microM). The effects on the APD and Ik were both partially reversed after perfusion with drug-free Tyrode's solution. The block of Ik by ambasilide was compared to that by E-4031 (5 microM), a putative selective blocker of that fast, inwardly rectifying component of Ik identified in guinea pig ventricle. E-4031 produced about 65% block of Ik for pulse durations between 80 and 420 msec, but the block decreased as the pulse duration increased further, the block accounting for 34 +/- 5% of Ik at 6.3 sec. In contrast, the percentage of reduction of Ik by 10 microM ambasilide did not produce a consistent magnitude of block over a similar range of short depolarizations, but rather progressively decreased Ik as the pusle duration lengthened. Block at the end of a 2-sec pulse was about 48 +/- 8%, more block than could be attributed to an E-4031-sensitive current block alone. Whereas E-4031 (5 microM) shifted the activation curve of Ik 10 mV toward positive potentials and decreased the slope factor, k, by about 4 mV, ambasilide (5 microM) had no effect on these parameters.(ABSTRACT TRUNCATED AT 250 WORDS)

Electromechanical effects of the putative potassium channel activator celikalim (WAY-120,491) on feline atrial and ventricular muscle.

Celikalim (WAY-120,491) is a putative potassium channel activator that has been shown to lower blood pressure in animal models and humans. In the present study, we have examined the effects of celikalim on contractility and ionic currents in feline cardiac muscle. Celikalim was found to decrease contractility in electrically stimulated (2 Hz frequency) left atrial and right ventricular papillary muscle preparations with IC50 values of 0.95 +/- 0.12 microM (n = 6) and 0.29 +/- 0.07 microM (n = 5), respectively. Glyburide (1 microM) reversed the celikalim-induced negative inotropy (left atrial halves). Celikalim was also shown to activate a glyburide-sensitive current in voltage-clamped isolated ventricular myocytes that reversed close to the calculated value of the potassium equilibrium potential (n = 4 cells). In addition, celikalim was found to inhibit voltage-activated calcium current (L-type) in isolated ventricular myocytes (51 +/- 2% inhibition at 1 microM; n = 4 cells). We conclude that celikalim is a potassium channel activator and hypothesize that both the negative inotropy and the glyburide-sensitive current evoked by this drug are mediated by ATP-regulated potassium channels. Inhibition of voltage-activated calcium channels by celikalim may also contribute to the negative inotropy induced by this drug.

Modulation of the delayed rectifier, IK, by cadmium in cat ventricular myocytes.

The effects of cadmium on the delayed outward potassium current (IK) were investigated in isolated cat ventricular myocytes using the single suction pipette voltage-clamp technique. IK activation was examined using peak tail currents elicited after 750-ms voltage-clamp steps to selected membrane potentials from a holding potential of -40 mV. In the presence of Cd2+ (0.2 mM), peak tail currents increased from a control value of 85 +/- 12 to 125 +/- 18 pA (n = 4). Activation curves constructed from the average peak tail-current measurements in all experiments showed that Cd2+ shifted the voltage dependence of activation to more positive potentials by 16.4 +/- 2.0 mV and increased the slope factor of the activation curve from 6.1 +/- 0.2 to 6.9 +/- 0.2 mV. In the absence of Cd2+, increases in holding potential from -30 to -70 mV had no effect on the magnitude of the peak tail currents, suggesting that the Cd(2+)-induced increase was not the result of a voltage-dependent increase in the number of available K+ channels at the holding potential. Slow voltage ramps from -70 to +70 mV revealed that Cd2+ increased the outward current at membrane potentials positive to +20 mV and shifted the voltage range in which IK inwardly rectified to more positive potentials. The fully activated current-voltage relationship was also shifted to more positive potentials by Cd2+. Cd2+ did not alter channel selectivity for K+.(ABSTRACT TRUNCATED AT 250 WORDS)

Channel specificity in antiarrhythmic drug action. Mechanism of potassium channel block and its role in suppressing and aggravating cardiac arrhythmias.

Although work on class III antiarrhythmics remains at an early stage, these agents still appear to possess greater efficacy and less proarrhythmia than conventional class I agents in those experimental arrhythmia models considered to be most representative of the clinical situation. Although prolongation of repolarization carries with its own tendency for pause-dependent arrhythmogenesis (i.e., torsade de pointes), available data suggest that this may be a function of nonspecificity in potassium channel block rather than a general characteristic of class III activity. The availability of new and more selective blockers of specific cardiac potassium channels under development as class III agents have already helped to clarify basic questions about the ionic mechanism of repolarization in the heart, and one hopes that a growing clinical data base will eventually determine the relative safety and efficacy of these agents in preventing symptomatic and life-threatening arrhythmias.

Block of delayed rectifier potassium current, IK, by flecainide and E-4031 in cat ventricular myocytes.

Block of the delayed rectifier potassium current, IK, by the class IC antiarrhythmic agent, flecainide, and by the novel selective class III antiarrhythmic agent, E-4031, were compared in isolated cat ventricular myocytes using the single suction-pipette, voltage-clamp technique. Flecainide (10 microM) markedly reduced IK elicited on depolarization steps to plateau voltages (+10 mV) and nearly completely blocked the "tail currents" elicited on repolarization to -40 mV (93 +/- 4% block at +40 mV, n = 3). E-4031 (1 microM) produced similar effects (96 +/- 3% block at +40 mV, n = 3). Slow voltage ramps from -100 to +40 mV confirmed inward rectifying properties of IK and showed that flecainide and E-4031 have no effects on the background potassium current, IK1. Thus, the results demonstrate that block of IK is a common feature of flecainide and E-4031. IK block by E-4031 most likely underlies the drug's potent class III antiarrhythmic properties. On the other hand, flecainide block of IK during an action potential would tend to prolong repolarization, but this effect may be obscured by concomitant block of plateau Na+ channels to produce little or no change in action potential duration, consistent with its class IC classification.

Amiodarone blocks calcium current in single guinea pig ventricular myocytes.

Ca++ current (lca) block by amiodarone and the underlying mechanisms thereof were investigated in guinea pig single ventricular myocytes using the single suction pipette whole cell voltage clamp method. The dose-response curve revealed a 1:1 stoichiometry for binding of amiodarone to its receptor with an apparent dissociation constant of 5.8 microM in the resting state. Amiodarone, 5 microM did not significantly alter the time course of ICa decay, but did shift the steady-state inactivation curve for lca in the hyperpolarizing direction by 9.2 +/- 3.1 mV. Development of block at depolarized potentials was voltage-dependent between -20 and 10 mV with time constants of 112 +/- 33 and 755 +/- 212 msec at 10 mV. In the presence of 0.2 microM amiodarone, recovery from inactivation was fitted by a double exponential most likely indicating rapid recovery of the drug-free Ca++ channels and slow recovery of the drug-associated Ca++ channels with time constants of 44 +/- 12 and 108 +/- 403 msec, respectively, at -80 mV. The proportion of the current recovering via the slow phase was 36 +/- 7%. By using this value, we estimated the dissociation constant in the inactivated state to be 0.36 microM. Amiodarone's marked use-dependent block of lca is explicable in terms of its high affinity for, and slow dissociation from, Ca++ channels in the inactivated state. These results suggest that amiodarone blocks lca in both the resting and inactivated states.(ABSTRACT TRUNCATED AT 250 WORDS)

Evidence for two components of sodium channel block by lidocaine in isolated cardiac myocytes.

The effects of lidocaine on sodium current in cardiac myocytes isolated from cat and guinea pig were investigated using the whole-cell variation of the patch-clamp technique. Lidocaine (43-200 microM) reduced sodium current during repetitive depolarizing pulses in a use-dependent manner. To clarify the nature of the use-dependent block, we characterized the time course of block development using a two-pulse protocol. Two distinct phases of block development were found: a rapid phase (tau = 1-6 msec) having a time course concurrent with the time course of channel activation, and a slower phase (tau = 100-900 msec), which developed after channels inactivated. The amplitude of the block during the rapid phase of development was a steep function of transmembrane voltage over the range of -70 to +20 mV. The voltage-dependence was similar to that for sodium channel activation (sodium conductance) but was too steep to be attributed solely to the passive movement of a singly charged molecule under the influence of the transmembrane voltage gradient. These results suggest that use-dependent block of sodium channels in cardiac tissue may result from an interaction of lidocaine with sodium channels in the activated as well as the inactivated channel states. Possible mechanisms underlying the fast component of block are discussed.

Amiodarone-induced block of sodium current in isolated cardiac cells.

Sodium current (INa) block by amiodarone (AMI) was investigated in isolated single Purkinje and ventricular myocardial cells using the single suction-pipette voltage-clamp technique. AMI produced marked resting block that was enhanced at low holding potentials, findings consistent with a shift in the steady-state INa availability curve to more negative potentials (-16 +/- 3 mV). Resting block was not associated with any change in the time course of INa decay during a depolarizing clamp step. AMI also produced use-dependent block in conjunction with increases in rate (0.5-5.0 Hz) and pulse duration (2-200 msec). These changes are consistent with a slowing of the recovery from inactivation of the sodium channel. Brief depolarizing pulses produced little use-dependent block, suggesting that the onset of drug-induced block is slow. Thus, AMI blocks INa and shifts the availability curve in isolated myocytes, both of which contribute to the net tonic block. The results suggest that both rested state and inactivated state sodium channel block are factors in AMI's antiarrhythmic efficacy.

Sodium current kinetics in cat atrial myocytes.

1. Na+ current kinetics were studied in isolated atrial myocytes from the adult cat using the single suction-pipette voltage-clamp technique. 2. Current-voltage and conductance-voltage relationships were similar to those described in other cardiac myocyte preparations. 3. Analysis of Na+ current decay using single-pulse, double-pulse and tail current measurements were in agreement and demonstrate a second-order process of current decay. 4. Voltage dependence of steady-state inactivation curves was not symmetrical, having an inflexion at about -90 mV. These results suggest more than a single inactivation process for Na+ channel in the negative potential region. 5. Recovery of Na+ current from inactivation had a sigmoid time course: an initial slow component (delay) followed by a fast and then a second slow component. Increasing the pre-pulse duration slowed the time course of recovery. 6. Taken together, the results were consistent with the presence of multiple inactivated states for the atrial myocyte Na+ channel.

Protective action of diazepam and of sympathomimetic amines against amitryptyline-induced toxicity.

Factors that contribute to the lethality of amitriptyline overdosage were studied in cats. Amitriptyline (50 mg/kg) given i.p. to unanesthetized cats produced convulsions in all of the animals and death in five of six animals; pretreatment with diazepam (5 mg/kg) protected against the convulsions and death. Respiratory depression contributed to the mortality when amitriptyline was given i.v. in cats anesthetized with pentobarbital as indicated by the finding that artificial respiration delayed the time of death induced by a continuous i.v. infusion of the drug. The i.v. infusion of amitriptyline in pentobarbitalized cats under artificial respiration produced death due to cardiovascular collapse. The latter was characterized by hypotension, bradycardia, depression of myocardial contractile force, atrioventricular block, intraventricular conduction delay and cardiac arrhythmias. These effects appear to be due to a direct membrane (quindine-like) cardiotoxic action of amitriptyline. Dopamine and dobutamine were effective in protecting the animals against the acute cardiovascular collapse induced by amitriptyline. The protection was associated with a diminution of the hypotension, the negative inotropic and chronotropic actions and the incidence of atrioventricular block produced by the tricyclic antidepressant drug. The results suggest that the positive chronotropic, inotropic and dromotropic actions of the amines may all be contributory factors in their protection action. Isoproterenol and norepinephrine were less effective than the other two amines.

Experimental studies on the effects of physostigmine and of isoproterenol on toxicity produced by tricyclic antidepressant agents.

The IV infusion of nortriptyline and amitriptyline (0.5 mg/kg/min) in anesthetized cats produced death within 60 min of continuous infusion. The tricyclic antidepressant agents produced a quinidine-like depression of the myocardium characterized by bradycardia, depression of contractile force, conduction defects, bradyarrhythmias, and hypotension. The simultaneous IV infusion of isoproterenol (0.1 microgram/ kg/min) produced significant protection against death produced by the TCA drugs. The results suggested that the positive chronotropic, inotropic, and dromotropic actions of isoproterenol may all be contributory factors in the protection. Pretreatment with a large dose of physostigmine (0.2 mg/kg) produced a rightward shift of the nortriptyline time-mortality curve. The small degree of protection produced by the anticholinesterase drug may be due to a respiratory stimulant action rather than a cardiac action.