Pinacidil increases the background potassium current in single ventricular cells

Effects of pinacidil, verapamil, and heart rate on afterdepolarizations in the guinea-pig heart in vivo

Recently, ionic current simulation in the Luo-Rudy model has elucidated putative mechanisms of afterdepolarizations under various experimental conditions. The present study was aimed at gaining insight into the differential mechanism of different types of afterdepolarizations in the guinea-pig heart in vivo. The effects of pharmacological and heart rate perturbations on early (EADs) and delayed (DADs) afterdepolarizations, induced by either digoxin, CsCl, or BayK 8644 were studied, using mid-myocardial left ventricular monophasic action potential (MAP) recordings. Digoxin insignificantly shortened sinus cycle length (SCL) and CsCl and BayK 8644 differentially prolonged SCL and MAP duration. Digoxin induced phase 3-EADs and DADs and CsCl or BayK 8644 induced phase 2- and phase 3-EADs. Pinacidil shortened MAP duration, suppressed almost all the phase 2-EADs and some of the phase 3-EADs, but not the DADs. In a few cases, DADs were manifested following the abolishment of phase 2-EADs by pinacidil, but this phenomenon did not occur in the presence of hexamethonium. Verapamil prolonged SCL, did not significantly affect phase 2-EADs, but suppressed almost all of the DADs, including those which appeared after pinacidil, and all but one of the phase 3-EADs. The effects of pinacidil and verapamil were independent of the mode of afterdepolarization induction. A pacing-induced heart rate increase, which shortened MAP duration, and vagal stimulation, which prolonged MAP duration, attenuated and enhanced phase 2-EADs, respectively. The amplitude of phase 3-EADs was inversely related to the heart rate. These data, taken together, are consistent with those obtained previously by others in a computer model and recent observations on CsCl-induced EADs in the guinea-pig Purkinje fibers in vitro which have indicated that the mechanism of phase 2-EADs is different from that of DADs and that late phase 3-EADs generated under conditions of Ca2+ overload and DADs share similar properties.

Effect of pinacidil on rat hearts undergoing hypothermic cardioplegia

We studied the effect of pinacidil, a potassium-channel opener, on the hemodynamic, biochemical, and ultrastructural changes in rat hearts undergoing hypothermic cardioplegia. Fifty-four male Wistar rats weighing 250 to 300 g were used. Isolated hearts were prepared for modified Langendorff circulation in the working mode using modified Krebs-Henseleit bicarbonate solution bubbled with a 95% O2 and 5% CO2 gas mixture. Eighty minutes of cardioplegia at 25 degrees C was followed by normothermic reperfusion for 30 minutes. Pinacidil, 5, 10, or 50 mumol/L added to the cardioplegic solution, did not affect heart rate, but is significantly improved the recovery of aortic flow as compared with controls (88.1% +/- 4.3 [5 mumol/L]; 83.2% +/- 8.5% [10 mumol/L]; 90.3% +/- 5.3% [50 mumol/L] compared with 55.6 +/- 4.3% [control]; p < 0.05). Administration of pinacidil during reperfusion did not further enhance the recovery of aortic flow. The dose-response curve of aortic flow to the pinacidil concentrations was flat from 5 to 50 mumol/L. However, preservation of myocardial adenosine triphosphate and calcium concentrations and mitochondrial morphology suggested that the optimal concentration of pinacidil cardioplegia is 10 mumol/L.

Negative inotropic effect of pinacidil on the rat left atria

Cromakalim at 50 microM and pinacidil at 0.1-10 microM had no effect, but pinacidil at 0.1 mM had a negative inotropic effect on the rat electrically-driven left atria without altering the positive inotropic responses to isoprenaline or phenylephrine alone. Glibenclamide had no effect but 4-aminopyridine, procaine (30 microM) and tetraethylammonium (3 mM) augmented the cardiac stimulation response. The ability of pinacidil to attenuate the cardiac stimulation response was not altered by glibenclamide, 4-aminopyridine or procaine but was prevented by pretreatment with tetraethylammonium. Thus, on the rat left atria, pinacidil has a negative inotropic effect which is unrelated to the opening of ATP-sensitive potassium channels, but may be due to opening the inward rectifying potassium channels.

Pro-arrhythmic effect of nicorandil in isolated rabbit atria and its suppression by tolbutamide and quinidine

Nicorandil, a potent vasodilator substance which exerts its effects through complex mechanisms including KATP channel activation, has so far been reported to exert antiarrhythmic but not pro-arrhythmic cardiac activity. We now examined the effects of 10(-4) M nicorandil on spontaneously active or electrically driven isolated rabbit atria. Nicorandil (a) significantly reduced the action potential duration at both 50% (by approximately 45%) and 80% (by approximately 30%) repolarization and the effective refractory period (by approximately 25%) and (b) reproducibly induced short periods of tachycardia either in normal Tyrode solution after a single extra-stimulus or in low-potassium media in the absence of extra-stimulation. Quinidine (10(-5) M) or the KATP channel inhibitor, tolbutamide (10(-5) M), suppressed the nicorandil-induced arrhythmias. It is suggested that the pro-arrhythmic effect of nicorandil results from its KATP channel opener activity and occurs essentially when the underlying conditions facilitate re-entry.

Effects of K+ channel agonists cromakalim and pinacidil on rat basilar artery smooth muscle cells are mediated by Ca(++)-activated K+ channels

Whole-cell and cell-free inside-out patch-clamp recording techniques were used to examine the actions of potassium channel openers pinacidil and cromakalim in enzymatically isolated smooth muscle cells of rat basilar artery. Delayed rectifier and calcium-dependent potassium currents were identified from the whole-cell recordings. Only the calcium-dependent potassium current was increased by cromakalim and pinacidil. Recordings from inside-out membrane patches revealed a large conductance voltage- and calcium-dependent potassium channel, which was blocked by charybdotoxin but unaffected by ATP less than 10 mM. Cromakalim and pinacidil increased the open probability of this channel. On the basis of these results, we suggest that such drugs, acting on cerebral arterial smooth muscle cell potassium channels, may be of some benefit in the treatment of cerebral vasospasm following subarachnoid hemorrhage.

A model of the ventricular cardiac action potential. Depolarization, repolarization, and their interaction

A mathematical model of the membrane action potential of the mammalian ventricular cell is introduced. The model is based, whenever possible, on recent single-cell and single-channel data and incorporates the possibility of changing extracellular potassium concentration [K]o. The fast sodium current, INa, is characterized by fast upstroke velocity (Vmax = 400 V/sec) and slow recovery from inactivation. The time-independent potassium current, IK1, includes a negative-slope phase and displays significant crossover phenomenon as [K]o is varied. The time-dependent potassium current, IK, shows only a minimal degree of crossover. A novel potassium current that activates at plateau potentials is included in the model. The simulated action potential duplicates the experimentally observed effects of changes in [K]o on action potential duration and rest potential. Physiological simulations focus on the interaction between depolarization and repolarization (i.e., premature stimulation). Results demonstrate the importance of the slow recovery of INa in determining the response of the cell. Simulated responses to periodic stimulation include monotonic Wenckebach patterns and alternans at normal [K]o, whereas at low [K]o nonmonotonic Wenckebach periodicities, aperiodic patterns, and enhanced supernormal excitability that results in unstable responses ("chaotic activity") are observed. The results are consistent with recent experimental observations, and the model simulations relate these phenomena to the underlying ionic channel kinetics.

Acute hemodynamic effects of pinacidil in hypertensive patients with and without propranolol pretreatment

To study the systemic and regional hemodynamic effects of the new antihypertensive agent pinacidil, the authors administered intravenously two doses of pinacidil (0.1 mg/kg) to patients with hypertension after 3 days of randomized, double-blind pretreatment with either propranolol or placebo. Pinacidil administration decreased systemic arterial pressure and total peripheral vascular resistance in both groups of patients. It also decreased pulmonary artery wedge pressure, and increased cardiac output, heart rate, and plasma norepinephrine levels; the changes in cardiac output and heart rate were attenuated by propranolol pretreatment. In addition, propranolol-pretreated patients responded to pinacidil with a decrease in forearm blood flow. In contrast, pinacidil administration exerted no significant effects on right atrial pressure, stroke volume, or mean pulmonary arterial pressure alone or in combination with propranolol. The results show that pinacidil is a potent arterial dilator but has little effect on the venomotor tone in patients with hypertension.

K+ channel blocking and anti-muscarinic effects of a novel piperazine derivative, INO 2628, on the isolated dog atrium

The effects of a novel piperazine derivative, INO 2628, on the negative inotropic and chronotropic responses to intracardiac parasympathetic nerve stimulation and carbachol, to adenosine and to the K+ channel openers, pinacidil and nicorandil, were investigated in isolated, blood-perfused dog heart preparations. INO 2628 (0.1-10 mumol) injected into the sinus node artery of the isolated atrium induced negative chronotropic and small positive inotropic responses in a dose-dependent manner. INO 2628 antagonized the negative chronotropic and inotropic responses to intracardiac vagus stimulation and carbachol in a dose-dependent manner, whereas INO 2628 did not antagonize the negative cardiac responses to adenosine. Pinacidil and nicorandil caused dose-dependent negative inotropic and small negative chronotropic responses in isolated atria and ventricles, suggesting that pinacidil-related K+ channels are much sparser in SA nodal pacemaker cells than in cardiac muscle cells. INO 2628 dose dependently antagonized the negative inotropic responses to pinacidil and nicorandil, but it did not modify the nicardipine-, pentobarbital- or G-strophanthin-induced cardiac responses. These results suggest that INO 2628 inhibits the negative cardiac effects of acetylcholine at muscarinic receptors and directly inhibits K+ channels in the isolated dog heart.

Interrelation between pinacidil and intracellular ATP concentrations on activation of the ATP-sensitive K+ current in guinea pig ventricular myocytes

The patch-clamp technique was used to study the relation between pinacidil and intracellular ATP concentration [( ATP]i) on the activation of the outward K+ current in guinea pig ventricular myocytes. Pinacidil shortened the action potential duration, exhibiting stronger effect at 2 mM [ATP]i than at 5 mM [ATP]i. Pinacidil at 5 microM or higher concentrations activated the time-independent outward current at potentials positive to -80 mV, and the pinacidil-activated current was suppressed by increasing [ATP]i from 2 to 5 mM. The dose-response curve of pinacidil at different [ATP]i showed a shift to the right and a depression of the maximum response at increased [ATP]i. The pinacidil-induced shortening of the action potential duration and outward current were inhibited by application of 0.3-1.0 microM glibenclamide. In single-channel current recordings, pinacidil activated the intracellular ATP-sensitive K+ channel current without changing the unitary amplitude, and increased open probability of the channel, an effect dependent on [ATP]i. The pinacidil-activated single-channel current was blocked by glibenclamide. These results prove the notion that pinacidil activates the ATP-sensitive K+ channel current, which explains the action potential shortening in cardiac cells after application of pinacidil.

Suppression of repolarization-related arrhythmias in vitro and in vivo by low-dose potassium channel activators

Marked prolongation of cardiac action potentials and of QT intervals has been associated with early afterdepolarizations and triggered activity in vitro and with ventricular tachycardia in vivo. Because the antihypertensive potassium channel activators pinacidil and cromakalim are known to accelerate repolarization in cardiac tissues, we performed in vitro and in vivo experiments to test the hypothesis that these agents would block the arrhythmogenic effects of delayed repolarization. Early afterdepolarizations and triggered activity were elicited in canine cardiac Purkinje fibers driven at cycle lengths of 4 seconds or more (K0, 2.7 mM) during superfusion with quinidine, cesium, or sematilide, a methylsulfonylamino parasubstituted analogue of procainamide with class III antiarrhythmic activity. The potassium channel activators invariably (17 of 17) abolished this form of abnormal automaticity. This effect was observed at low concentrations that did not alter action potential characteristics at shorter cycle lengths. Intravenous Cs+ (total dose, 4.5 mM/kg) was used to produce ventricular arrhythmias in anesthetized rabbits randomly pretreated in a double-blind fashion with either low-dose pinacidil (0.2 mg/kg) or vehicle. Pinacidil pretreatment resulted in significantly fewer total ventricular ectopic beats (168 +/- 157 versus 582 +/- 448, p less than 0.005) and episodes of ventricular tachycardia (four of nine versus nine of nine, p = 0.057). At this dose, pinacidil did not alter mean blood pressure before Cs+ and maximal hypertensive response after Cs+. In summary, the potassium channel activators pinacidil and cromakalim suppressed triggered activity related to prolonged repolarization at concentrations that did not affect action potential characteristics at normal rates in vitro; pinacidil blunted arrhythmias produced by cesium administration in vivo without lowering blood pressure.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of pinacidil on the electrophysiological properties in guinea-pig papillary muscle and rabbit sino-atrial node

The electrophysiological effect of the antihypertensive drug pinacidil has been examined in preparations of guinea-pig papillary muscle and rabbit sino-atrial node using a standard microelectrode method. In papillary muscle preparations, pinacidil (greater than 30 microM) shortened the action potential duration (APD), whereas it did not affect the maximum rate of rise (Vmax). Pinacidil (greater than 1 microM) also decreased APD of slow action potentials evoked by high K+ (27 mM) solution containing 0.2 mM Ba2+. At 30 microM, the drug reduced the Vmax of slow action potentials. In the spontaneously beating sino-atrial node, pinacidil (greater than 30 microM) shortened APD. At 100 microM, it also decreased the heart rate, Vmax, action potential amplitude and the rate of diastolic depolarization. It is concluded that pinacidil modifies the electrical activity of myocardial cells probably due to an increase in the potassium conductance although in high concentrations the compound might also reduce Ca2+ influx through the cell membrane, which would contribute to an obvious negative chronotropic action.

Potassium channel openers and vascular smooth muscle relaxation

Potassium channel openers comprise a diverse group of chemical agents which open plasma-lemmal K-channels. They show selectivity for smooth muscle, although K-channels in cardiac and skeletal muscle, neurones and the pancreatic beta-cell are also affected at relatively high concentrations. In addition, at least one endogenous K-channel opener of vascular origin--endothelium-derived hyperpolarizing factor--exists and in man plays a role in modulating blood vessel tone. The type of K-channel involved in the actions of both exogenous and endogenous K-channel openers is still uncertain, although a prime candidate in smooth muscle seems similar to the [ATPi]-modulated K-channel in the pancreatic beta-cell. This review focuses attention on the action of these agents in vascular smooth muscle and on the possible clinical exploitation of their powerful vasorelaxant properties.

Pinacidil activates the ATP-sensitive K+ channel in inside-out and cell-attached patch membranes of guinea-pig ventricular myocytes

Patch-clamp techniques were used to study the effects of pinacidil on the adenosine-5'-triphosphate (ATP)-sensitive K+ channel current in guinea-pig ventricular myocytes. In inside-out patches, the ATP-sensitive K+ channel current could be recorded at an internal ATP concentration of 0.5 mM or less and almost complete inhibition was achieved by raising the concentration to 2 mM. Application of pinacidil (10-30 microM) in the presence of 2 mM ATP restored the current, whereas 5 mM ATP antagonized the effect of pinacidil. The conductance of the channel at symmetrical K+ concentrations of 140 mM was 75 pS with a slight inward rectification at voltages positive to + 40 mV. There was no significant change in the conductance after application of pinacidil. In 0.5 mM ATP, at -80 mV, both the distributions of the open time and the life-time of bursts could be fitted by a single exponential. An increase in ATP concentration decreased the mean life-time of bursts, whereas pinacidil increased it with little increase in the mean open time. Closed time distributions of the channel were fitted by at least two exponentials, with a fast and a slow time constant. An increase in ATP concentration markedly increased the slow time constant associated with a decrease in the number of bursts, whereas the effect of pinacidil was opposite to that of increased ATP. These results indicate that pinacidil increases the open-state probability of the ATP-sensitive K+ channel.(ABSTRACT TRUNCATED AT 250 WORDS)

Potassium channel openers act through an activation of ATP-sensitive K+ channels in guinea-pig cardiac myocytes

In a previous article (Escande et al. 1988a), we have shown that cromakalim (BRL 34915), a potassium channel opener (PCO), is a potent activator of ATP-sensitive K+ channels in cardiac cells. In the present article, the influence on K+ channels of two other potassium channel openers chemically unrelated to cromakalim, RP 49356 and pinacidil, has been investigated in patch-clamped isolated cardiac myocytes. In the whole-cell configuration, K+ currents were recorded in the presence of 50 microM TTX and 3 microM nitrendipine or 3 mM cobalt. Like cromakalim, RP 49356 or pinacidil activated a time-independent outward current at 33-35 degrees C but not at 19-21 degrees C, which showed little voltage-dependency in the potential range -60 to +60 mV. Its amplitude was a function of the agonist concentration, e.g. it was 2.1 +/- 0.4 nA at +60 mV with 30 microM RP 49356 and 4.3 +/- 0.8 nA with 300 microM. In control conditions, glibenclamide, a blocker of K+-ATP channels in pancreatic and heart cells, affected neither the inward rectifier, iK1, nor the delayed K+ current, iK. At 3 microM, glibenclamide fully prevented the effects of 300 microM RP 49356 or pinacidil. At lower concentrations, glibenclamide partially counteracted the activation by PCOs of a K+ current. In the cell-attached configuration, externally applied RP 49356 or pinacidil caused opening of large channels which reversed around O mV in a high K+ external medium. In inside-out patches, both RP 49356 or pinacidil activated K+-ATP channels by increasing the time period for which the channels remained in the open state. It is concluded that, like cromakalim, RP 49356 and pinacidil are potent activators of K+-ATP channels in cardiac myocytes.

Enhancement of potassium-sensitive current in heart cells by pinacidil. Evidence for modulation of the ATP-sensitive potassium channel

Pinacidil belongs to a novel group of compounds that enhance the potassium permeability of vascular smooth muscle. Evidence also exists that this drug enhances the potassium permeability of cardiac tissue. The purpose of the present investigation was to determine if pinacidil alters potassium-channel activity in heart and, if so, which potassium channel is the target. We used the whole-cell arrangement of the patch voltage clamp to record membrane currents from isolated guinea pig ventricular cells. In solutions designed to isolate potassium currents, pinacidil enhances a time-independent current positive to the potassium equilibrium potential. Current measured at voltages negative to the potassium equilibrium potential are essentially unaltered by the drug. The potassium sensitivity of outward current indicates that the target for the drug is a potassium channel. Experiments designed to test for voltage-dependent channel gating strongly suggest that the pinacidil-sensitive current is not voltage gated. Pinacidil-sensitive current is blocked by externally applied Ba2+, Cs+, and tetraethylammonium ion. In addition, it is potently blocked after external application of 100 nM glibenclamide. Taken along with the time- and voltage-independent properties of pinacidil-sensitive current, this pharmacology strongly suggests that the target for pinacidil in heart is the ATP-sensitive potassium channel.

Cardiohemodynamic effects of cromakalim and pinacidil, potassium-channel openers, in the dog, special reference to venous return

The cardiohemodynamic effects of the potassium-channel openers, cromakalim and pinacidil, were studied by the use of the closed-loop method (for both drugs) and the cardiopulmonary bypass technique (for cromakalim only) in anesthetized, open-chest dogs. In closed-loop preparations, both drugs (cromakalim, 3 to 100 micrograms/kg; pinacidil, 10 to 300 micrograms/kg) administered intravenously decreased systemic blood pressure and increased venous return (sum of the flow through the inferior and the superior vena cava) and cardiac output (CO). With the highest doses of both drugs, venous return and CO decreased in some preparations in which right atrial pressure rose, and the maximum rate of rise of left ventricular pressure (LV dP/dt max) diminished. Except such preparations, right atrial pressure, heart rate, and atrioventricular conduction time remained virtually unchanged. The fall in systemic blood pressure produced by intermediate doses of pinacidil was greater in the preparations in which baroceptor reflexes were eliminated (denervated preparations) than in those with the reflexes left intact (nerve-intact preparations). The increases in venous return and CO, however, were not different when comparing the nerve-intact and the denervated preparations. In cardiopulmonary-bypass preparations, higher doses of cromakalim increased venous return while producing a fall in systemic blood pressure, suggesting that the decreased venous return and CO seen with higher doses of the potassium-channel openers in the closed-loop preparations were secondary to the decreased cardiac contractility. The potassium-channel openers should be characterized as vasodilators, which preferentially reduce afterload and increase venous return.

Interaction of potassium channel openers and blockers in canine atrial muscle

1. The possibility that the interaction between potassium channel openers, e.g. cromakalim, pinacidil and nicorandil, and some potassium channel blockers involves a common site was investigated in canine atrial muscle. 2. Cromakalim, pinacidil and nicorandil produced a negative inotropic effect, their pD2 (-log EC50) values being 6.11 +/- 0.07, 5.37 +/- 0.09 and 4.55 +/- 0.07, respectively. 3. The potassium channel blockers, tetraethylammonium (TEA), tetrabutylammonium (TBA), 3,4-diaminopyridine (DAP), CsCl and BaCl2 all produced a positive inotropic effect. 4. The concentration-effect curves for the negative inotropic actions of pinacidil were shifted in a parallel way to the right by low concentrations of TEA, TBA or BaCl2. Maximum responses to pinacidil were depressed by higher concentrations of the blockers. An analysis of the non-competitive antagonism by TEA yielded pKA (-log KA) values of 4.00-4.05 for pinacidil. 5. The concentration-effect curves for cromakalim and nicorandil were shifted by TEA similarly to those for pinacidil, and a similar analysis yielded pKA values of 4.47-4.68 for cromakalim and 3.47-3.74 for nicorandil. 6. The KA values of cromakalim, pinacidil and nicorandil were about 10-30 times greater than their EC50 values, indicating that there are non-linear stimulus-effect relationships between the binding of the three potassium channel openers to their binding sites at potassium channels and their negative inotropic effects. 7. The dissociation constants for TEA could also be estimated from pA2 and pKB values for antagonizing competitively and non-competitively the negative inotropic effects of the three potassium channel openers; they were 3.47-3.89, and did not differ between the potassium channel openers. 8. The concentration-effect curves for the three potassium channel openers were not affected by DAP or CsCl. 9. These results suggest the following: (i) quaternary ammonium compounds like TEA and TBA antagonize the negative inotropic effect of cromakalim, pinacidil and nicorandil by binding to potassium channels, thus preventing binding of the channel openers to the same sites or closely related sites in canine right atrial muscles.

Nicorandil as a hybrid between nitrates and potassium channel activators

Nicorandil, although structurally a nitrate, differs from classic nitrates in several respects. It preferentially dilates resistive vessels. Its effect on venous return in dogs is not unanimously a decrease but rather an increase. In high doses or concentrations it suppresses myocardial contraction and ventricular automaticity, nearly sparing sinoatrial nodal automaticity and atrioventricular nodal conduction. It shortens the effective refractory period of myocardium. These cardiac effects of nicorandil have been explained by its mechanism of action as a potassium (K) channel activator. However, what part of the vascular effects of nicorandil this mechanism is responsible for has not been determined. BRL 34915 and pinacidil, nonnitrate vasodilators with a K-channel activator action, have essentially the same cardiovascular profile as nicorandil in isolated, blood-perfused canine heart preparations. In anesthetized, open-chest dogs the 2 K-channel activators decreased systemic blood pressure and increased venous return and cardiac output without elevating heart rate, unless the cardiodepressant effect emerged. The increase in venous return or cardiac output survived elimination of baroceptor functions. These results taken together with previous results on nicorandil suggest the following: (1) The property of nicorandil as a resistive vessel dilator highly selective for vasculature originates in its mechanism of action as a K-channel activator. The nonunanimous effect of nicorandil on venous return is a result of the opposing actions as a capacitive (action as a nitrate) and a resistive vessel dilator. Nicorandil, with its hybrid nature, is advantageous over specific K-channel activators and classic nitrates in therapeutic implications.

A novel cardiac potassium channel that is active and conductive at depolarized potentials

We report the existence of a novel potassium channel revealed in single-channel recordings from guinea-pig ventricular heart cells. The channel, observed in approximately 10% of patches, demonstrates a 14 pS conductance at physiological potassium concentrations, does not rectify over the voltage range of the action potential, and is quite selective for K ions. The channel activates with depolarization, but does not require intracellular Ca2+ ions to open. Open channel probability increases rapidly (less than 10 ms) to a plateau in response to depolarizing voltage steps, and demonstrates no detectable inactivation (greater than 600 ms). These features clearly distinguish this channel from other known K channels in cardiac muscle. Because of its high activity at plateau potentials, we propose the name iKp.

BRL 34915 (cromakalim) activates ATP-sensitive K+ current in cardiac muscle

The mechanism by which the antihypertensive agent BRL 34915 (cromakalim) affects action potential duration (APD) and effective refractory period (ERP) in isolated cardiac muscle was investigated. BRL 34915 (greater than or equal to 3 microM) shortened ERP of ferret (Mustela putorius furo) and guinea pig (Cavia porcellus) papillary muscles in a concentration-dependent fashion. The reduction in ERP resulted from a decrease in APD. ERP and APD of papillary muscles were also reduced during hypoxia produced by bubbling the physiological bathing solution with N2 instead of O2. Reduction of APD during hypoxia has previously been attributed to activation of ATP-sensitive K+ channels in heart. Glyburide, an inhibitor of ATP-sensitive K+ channels, prevented or reversed the shortening of ERP and APD produced by hypoxia and BRL 34915, respectively. These results suggest that BRL 34915 acts by opening ATP-sensitive K+ channels in heart. The actions of BRL 34915 were temperature-dependent, decreasing ERP 64% at 37 degrees C, but having no effect at 22 degrees C. The effect of BRL 34915 on K+ currents was tested directly in voltage-clamped guinea pig ventricular myocytes. As observed with the papillary muscles, BRL 34915 was without effect at 22 degrees C. At 36 degrees C, BRL 34915 (after a delay) increased outward currents positive to, and less so at potentials negative to, the K+ current reversal potential. The normal inwardly rectifying current-voltage relationship for peak K+ currents during 200-msec pulses was changed to one that was nearly ohmic. The current activated by BRL 34915 was blocked by glyburide. The data support the hypothesis that BRL 34915, like hypoxia, activates ATP-sensitive K+ channels in the heart. Based upon the profound temperature sensitivity of BRL 34915 action, this activation may be indirect, perhaps by means of modulation of an enzymatic activity that regulates gating of these channels. BRL 34915 and glyburide will be valuable tools for studying the role of ATP-sensitive K+ channels in normal and abnormal cardiac function.

The negative inotropic effect of nicorandil is independent of cyclic GMP changes: a comparison with pinacidil and cromakalim in canine atrial muscle

1. The negative inotropic effects of nicorandil, a nitrate with K-channel opening properties, have been compared with those of pinacidil, cromakalim and nifedipine, in canine right atrial muscle. 2. Cromakalim, pinacidil and nicorandil all produced a negative inotropic effect. However, even at their maximally effective concentrations, the force of contraction remained at about 10% of control levels, whereas contraction was abolished by nifedipine. 3. The pD2 values for the negative inotropic effects of cromakalim, pinacidil and nicorandil were 5.93, 5.37, and 4.35, respectively. 4. The negative inotropic effects of cromakalim (3 x 10(-5)M), pinacidil (3 x 10(-5) M and 3 x 10(-4) M) and nicorandil (3 x 10(-5) M) were not accompanied by changes in cyclic AMP and cyclic GMP levels, whereas that of 3 x 10(-4) M nicorandil was accompanied by an increase in cyclic GMP but not cyclic AMP concentrations. 5. The negative inotropic effect produced by 3 x 10(-4) M nicorandil was greatly reduced by 10(-2) M tetraethylammonium, whereas the increase in cyclic GMP produced by this concentration of nicorandil was not significantly changed. Sodium nitroprusside (10(-3) M) produced a large increase in cyclic GMP concentrations but had no significant negative inotropic effect. 6. It is concluded that the negative inotropic effects of nicorandil like those of cromakalim and pinacidil do not result from an increase in cyclic GMP concentrations. Instead these effects may be due to their action as K-channel openers.

The potassium channel opener cromakalim (BRL 34915) activates ATP-dependent K+ channels in isolated cardiac myocytes

In cardiac myocytes, cromakalim (BRL 34915), a potassium channel opener, activates a time-independent K+ current exhibiting poor voltage-sensitivity. This effect of cromakalim is antagonized by low concentrations of glibenclamide, a specific blocker of ATP-dependent K+ channels in cardiac cells. Direct recording of the activity of K+ channels in inside-out membrane patches, confirmed that cromakalim is a potent activator of ATP-dependent K+ channels in cardiac myocytes.