Pharmacologic characterization of BMS-191095, a mitochondrial K(ATP) opener with no peripheral vasodilator or cardiac action potential shortening activity.

Previous work described ATP-sensitive K(+) channel (K(ATP)) openers (e.g., BMS-180448), which retain the cardioprotective activity of agents such as cromakalim while being significantly less potent as vasodilators. In this study, we describe the pharmacologic profile of BMS-191095, which is devoid of peripheral vasodilating activity while retaining glyburide-reversible cardioprotective activity. In isolated rat hearts subjected to 25 min of global ischemia and 30 min of reperfusion, BMS-191095 increased the time to onset of ischemic contracture with an EC(25) of 1.5 microM, which is comparable to 4.7 microM and 3.0 microM for cromakalim and BMS-180448, respectively. Comparisons of cardioprotective and vasorelaxant potencies in vitro and in vivo showed BMS-191095 to be significantly more selective for cardioprotection with virtually no effect on peripheral smooth muscle, whereas cromakalim showed little selectivity. In addition to increasing the time to the onset of contracture, BMS-191095 improved postischemic recovery of function and reduced lactate dehydrogenase release in the isolated rat hearts. The cardioprotective effects of BMS-191095 were abolished by glyburide and sodium 5-hydroxydecanoate (5-HD). BMS-191095 did not shorten action potential duration in normal or hypoxic myocardium within its cardioprotective concentration range nor did it activate sarcolemmal K(ATP) current (< or =30 microM). BMS-191095 opened cardiac mitochondrial K(ATP) with a K(1/2) of 83 nM, and this was abolished by glyburide and 5-HD. These results show that the cardioprotective effects of BMS-191095 are dissociated from peripheral vasodilator and cardiac sarcolemmal K(ATP) activation. Agents like BMS-191095 may owe their cardioprotective selectivity to selective mitochondrial K(ATP) activation.

Cardioselective antiischemic ATP-sensitive potassium channel (K(ATP)) openers. 6. Effect of modifications at C6 of benzopyranyl cyanoguanidines.

The effect on potency and selectivity of modifications at the C6 position of the cardioprotective K(ATP) opener BMS-180448 (2) is described. Structure-activity studies show that a variety of electron-withdrawing groups (ketone, sulfone, sulfonamide, etc.) are tolerated for cardioprotective activity as measured by EC(25) values for an increase in time to the onset of contracture in globally ischemic rat hearts. Changes made to the sulfonamido substituent indicate that compounds derived from secondary lipophilic amines are preferred for good cardioprotective potency and selectivity. The diisobutyl analogue 27 (EC(25) = 0.04 microM) is the most potent compound of this series. The cardiac selectivity of 27 results from a combination of reduced vasorelaxant potency and enhanced cardioprotective potency relative to the potent vasodilating K(ATP) openers (e.g., cromakalim). The diisobutylsulfonamide analogue 27 is over 4 orders of magnitude more cardiac selective than cromakalim (1). These results support the hypothesis that the cardioprotective and vasorelaxant properties of K(ATP) openers follow distinct structure-activity relationships. The mechanism of action of 27 appears to involve opening of the cardiac K(ATP) as its cardioprotective effects are abolished by the K(ATP) blocker glyburide.

Preconditioning in rat hearts is independent of mitochondrial F1F0 ATPase inhibition.

Mitochondrial F1F0 adenosinetriphosphatase (ATPase) is responsible for the majority of ATP synthesis during normoxic conditions, but under ischemic conditions it accounts for significant ATP hydrolysis. A previous study showed that preconditioning in isolated rat hearts is mediated by inhibition of this ATPase during ischemia. We tested this hypothesis in our isolated rat heart model of preconditioning. Preconditioning was accomplished by three 5-min periods of global ischemia separated by 5 min of reperfusion. This was followed by 20 min of global ischemia and 30 min of reperfusion. Preconditioning significantly enhanced reperfusion contractile function and reduced lactate dehydrogenase release but paradoxically reduced the time to onset of contracture during global ischemia. Myocardial ATP was depleted at a faster rate during the prolonged ischemia in preconditioned than in sham-treated hearts, which is consistent with the reduced time to contracture. ATP during reperfusion was repleted more rapidly in preconditioned hearts, which is consistent with their enhanced contractile function. Preconditioning significantly reduced lactate accumulation during the prolonged ischemia. We were not able to demonstrate that mitochondrial F1F0 ATPase (measured in submitochondrial particles) was inhibited by preconditioning before or during the prolonged ischemia. The mitochondrial ATPase inhibitor oligomycin significantly conserved ATP during ischemia and increased the time to the onset of contracture, which is consistent with inhibition of the mitochondrial ATPase. Our results show that preconditioning in rat hearts can be independent of mitochondrial ATPase inhibition as well as ATP conservation.

Adenosine A1 receptor blockade does not abolish the cardioprotective effects of the adenosine triphosphate-sensitive potassium channel opener bimakalim.

There has been controversy regarding whether ATP-sensitive potassium channel activation protects hearts through adenosine A1 receptor activation or the converse. We addressed this issue by determining the effect of the adenosine A1 receptor antagonist 8-cyclopentyl-1,3-dipropylxanthine (DPCPX) on the cardioprotective activity of the ATP-sensitive potassium channel opener bimakalim. In isolated rat hearts subjected to 25 min of global ischemia and 30 min of reperfusion, bimakalim significantly reduced lactate dehydrogenase release and improved postischemic recovery of contractile function. Bimakalim increased the time to the onset of ischemic contracture (EC25 = 1.2 microM), compared with vehicle, and 10 microM DPCPX had no effect on this protective action (EC25 = 1.1 microM). The 10 microM concentration of DPCPX was sufficient to abolish the bradycardic and cardioprotective effects of the adenosine A1 receptor agonist (R)-(-)-N6-(2-phenylisopropyl)adenosine. DPCPX alone had no effect on the severity of ischemia/reperfusion damage. Glyburide completely abolished the cardioprotective effects of bimakalim. Bimakalim (1 microg/kg, intracoronarily) given over four periods of 5 min, interspersed with 10-min drug-free periods, before a 60-min occlusion and 3-hr reperfusion significantly reduced infarction size in anesthetized dogs (25 +/- 5 and 8 +/- 2% of the left ventricular area at risk for vehicle- and bimakalim-treated groups, respectively). DPCPX had no effect on the infarction-sparing activity of bimakalim (9 +/- 3% of the left ventricular area at risk). The protective effect of bimakalim was not accompanied by marked hemodynamic changes or by changes in regional myocardial blood flow. The results of this study suggest that the cardioprotective effects of ATP-sensitive potassium channel openers are not dependent on adenosine A1 receptor activation in rat or dog models of ischemia.

Cardioselective antiischemic ATP-sensitive potassium channel (KATP) openers. 5. Identification of 4-(N-aryl)-substituted benzopyran derivatives with high selectivity.

This paper describes our studies aimed at the discovery of structurally distinct analogs of the cardioprotective KATP opener BMS-180448 (2) with improved selectivity for the ischemic myocardium. The starting compound 6, derived from the indole analog 4. showed good cardioprotective potency and excellent selectivity compared to 2 and the first-generation KATP opener cromakalim (1). The structure-activity studies indicate that increasing the size of the alkyl ester leads to diminished potency as does its replacement with a variety of other groups (nitrile, methyl sulfone). Replacement of the ethyl ester of 6 with an imidazole gave the best compound 3 (BMS-191095) of this series which maintains the potency and selectivity of its predecessor 6. The results described in this publication further support that there is no correlation between vasorelaxant and cardioprotective potencies of KATP openers. Compound 3 is over 20- and 4000-fold more selective for the ischemic myocardium than 2 and cromakalim (1), respectively. The selectivity for the ischemic myocardium is achieved by reduction of vasorelaxant potency rather than enhancement in antiischemic potency. As for cromakalim (1) and 2, the cardioprotective effects of compound 3 are inhibited by cotreatment with the KATP blocker glyburide, indicating that the KATP opening is involved in its mechanism of cardioprotection. With its good oral bioavailability (47%) and plasma elimination half-life (3 h) in rats, compound 3 offers an excellent candidate to investigate the role of residual vasorelaxant potency of 2 toward its cardioprotective activity in vivo.

Glyburide-reversible cardioprotective effects of BMS-180448: functional and energetic considerations.

Adenosine triphosphate (ATP)-sensitive potassium channel openers as a class exert cardioprotective effects, and we can separate vasodilator from glyburide-reversible cardioprotective activity in cromakalim analogs (e.g., BMS-180448). The purpose of this study was to determine the relation between cardiac function, energy status, and cardioprotective effects for BMS-180448 in isolated rat hearts compared with diltiazem. BMS-180448 (1-30 microM) or 0.1-1 microM diltiazem were given 10 min before 25-min global ischemia in rat hearts followed by 30 min of reperfusion. Both compounds significantly increased time to the onset of contracture during ischemia and improved postischemic recovery of contractile function in a concentration-dependent manner. At equivalent cardioprotective concentrations, BMS-180448 depressed preischemic cardiac function significantly less than did diltiazem. During ischemia, diltiazem significantly accelerated the functional decline observed in vehicle-treated hearts, whereas BMS-180448 attenuated the net rate of decline of function. Despite these different effects on preischemic and ischemic cardiac function, diltiazem and BMS-180448 conserved cardiac ATP during ischemia to a similar degree. BMS-180448 enhanced the recovery of ATP (also seen for diltiazem, but not to the same magnitude) and creatine phosphate during reperfusion compared with vehicle-treated hearts. For BMS-180448, this enhanced ATP recovery was accompanied by a significant improvement in the efficiency of oxygen use, which was profoundly reduced in reperfused vehicle-treated hearts. BMS-180448 also significantly enhanced the functional reserve after the 25-min period of global ischemia. Thus BMS-180448 protects ischemic myocardium and conserves ATP with less reduction in cardiac function compared with diltiazem.

Lack of a pharmacologic interaction between ATP-sensitive potassium channels and adenosine A1 receptors in ischemic rat hearts.

OBJECTIVES: An interaction between adenosine A1 receptors and ATP-sensitive potassium channels (KATP) has been hypothesized to mediate preconditioning in several species. Unlike other species tested, KATP blockers and A1 antagonists do not abolish preconditioning in rat hearts. The purpose of this study was to determine if KATP and A1 receptors are pharmacologically linked in rat hearts as they are in other species. METHODS: Isolated rat hearts were given 0.03-1.00 microM R-PIA (adenosine A1 receptor agonist) with or without concomitant 0.3 microM glyburide starting 10 min pre-ischemia. After 25 min global ischemia, the hearts were reperfused for 30 min. Rat hearts were also treated with 1-30 microM cromakalim in the presence of 10 microM DPCPX (adenosine A1 antagonist). RESULTS: R-PIA produced a concentration-dependent bradycardia before ischemia which was blocked by DPCPX. R-PIA increased the time to onset of contracture in a concentration-dependent manner (EC25 = 0.13 microM) and this was unaffected by 0.3 microM glyburide (EC25 = 0.20 microM). This concentration of glyburide completely abolished the protective effects of 10 microM cromakalim. R-PIA also significantly enhanced post-ischemic recovery of function and reduced LDH release, and glyburide did not alter these responses. Cromakalim significantly increased the time to onset of contracture (EC25 = 4.5 microM) and 10 microM DPCPX had no effect on this (EC25 = 5.6 microM). Cromakalim also significantly enhanced post-ischemic recovery of function and reduced LDH release. DPCPX did not alter these cardioprotective effects while glyburide completely abolished the cardioprotective effects of cromakalim. CONCLUSIONS: While both cromakalim and R-PIA are cardioprotective in isolated rat hearts, they are not pharmacologically linked, possibly explaining why preconditioning may be different in this species.

Hemodynamic and cardiac effects of BMS-180448, a novel K+ATP opener, in anesthetized dogs and isolated rat hearts.

Hemodynamic and cardiac effects of BMS-180448 (0.3-10 mg/kg i.v.) or cromakalim (0.01-0.3 mg/kg i.v.) were evaluated in anesthetized open-chest dogs and isolated perfused rat hearts. In the canine studies, heart rate (HR), mean arterial pressure and left ventricular pressure were measured as well as electromagnetic blood flows recorded from the aortic, renal, coronary and femoral vascular beds. BMS-180448 was 187-fold less potent than cromakalim in lowering blood pressure (ED-20 values of 7.84, and 0.042 mg/kg for BMS-180448 and cromakalim, respectively). Both compounds increased HR. Effects of BMS-180448 occurred at doses higher than those of cromakalim, but at doses slightly lower than those needed to cause hypotension (ED(HR)/ED(MABP) ratio of 0.18 for BMS-180448). BMS-180448 had no effect on myocardial contractility or relaxation over the doses studied, whereas cromakalim significantly increased +dP/dt and lowered -dP/dt. Effects on +dP/dt were associated with a decrease in blood pressure. Although BMS-180448 reduced total peripheral resistance (ED-25 = 5.75 mg/kg), it had little effect on specific vascular beds, with the exception of the coronary bed. BMS-180448, unlike cromakalim which caused more general vasodilating effects, appeared to be relatively selective in dilating the coronary vascular bed. In isolated perfused rat hearts, BMS-180448, 10-fold more potent as a cardioprotectant (EC25 = 2.7 microM) than as a cardiodepressant (ED-25 = 27.8 microM), had no effect on HR, suggesting a lack of effect of BMS-180448 on myocardial conduction. In conclusion, BMS-180448, a recently developed K+ATP opener, exerted less hypotensive and more selective vascular effects than did cromakalim. These results suggest that BMS-180448, at doses previously reported to give cardioprotection, should have a safe hemodynamic profile.

Cardioselective antiischemic ATP-sensitive potassium channel openers. 4. Structure-activity studies on benzopyranylcyanoguanidines: replacement of the benzopyran portion.

The results of our efforts aimed at the replacement of the benzopyran ring of the lead cardiac selective antiischemic ATP-sensitive potassium channel (KATP) opener (4) are described. Systematic modification of the benzopyran ring of 4 resulted in the discovery of a structurally simpler acyclic analog (8) with slightly lower antiischemic potency than the lead compound 4. Further structure-activity studies on the acyclic analog 8 provided the 2-phenoxy-3-pyridylurea analog 18 with improved antiischemic potency and selectivity compared to the benzopyran-based compound 4. These data demonstrate that the benzopyran ring of 4 and its congeners is not mandatory for antiischemic activity and cardiac selectivity. The results described in this paper also show that, as for the benzopyran class of compounds, the structure-activity relationships for the antiischemic and vasorelaxant activities of KATP openers are distinct. The mechanism of action of the acyclic analogs (e.g., 18) still appears to involve KATP opening as their cardioprotective effects are abolished by pretreatment with the KATP blocker glyburide.

A comparison between the effects of BMS-180448, a novel K+ channel opener, and cromakalim in rat and dog.

BMS-180448 [(3S-trans)-N-(4-chlorophenyl)-N'-cyano-N"-(6-cyano-3, 4-dihydro-3-hydroxy-2,2-dimethyl-2H-1-benzopyran-4-yl) guanidine] is a structural analog of cromakalim, which was found to similarly decrease ischemic injury, but was 18- to 100-fold less potent as a vasodilator. In the present study, the vascular and cardiac effects of cromakalim and BMS-180448 were evaluated in both in vitro and in vivo preparations. Cromakalim evoked a concentration-dependent relaxation to a K(+)-induced contracture in rat aorta. BMS-180448 behaved in a similar fashion but was 18-fold less potent than cromakalim. Measurements of ischemic damage made in isolated perfused rat hearts demonstrated that cromakalim and BMS-180448 were equipotent as cardioprotective agents; time to contracture was increased with an EC25 value of 4.8 and 4.7 microM, respectively, and lactate dehydrogenase levels were significantly reduced compared to those in the presence of vehicle. In vivo electrophysiologic studies in anesthetized dogs were conducted at basic cycle lengths of 400, 333, and 286 ms, and showed that BMS-180448 caused no significant effect on electrophysiologic parameters with the exception of decreasing atrial effective refractory periods by 12 +/- 3% and 17 +/- 4% at 3 and 10 mg/kg, respectively. There was also a significant drop in mean blood pressure of 18 +/- 5% and 33 +/- 4% at these doses. In contrast, cromakalim was shown to produce shortening of atrial to His conduction time (20 +/- 7%; basic cycle length = 286 ms), atrial effective refractory period (34 +/- 3%; basic cycle length = 400 ms), ventricular effective refractory period (14 +/- 2%; basic cycle length = 400 ms), wavelength (13 +/- 3%; basic cycle length = 400 ms), PR-interval (14 +/- 3%; basic cycle length = 333 ms) and mean blood pressure (65 +/- 3%; basic cycle length = 400 ms) at a dose of 0.3 mg/kg. No supraventricular or ventricular arrhythmias were observed for either compound tested. Based on the reduced cardiac electrophysiologic and vascular effects of BMS-180448, we suggest that BMS-180448 should provide cardioprotective efficacy similar to cromakalim with reduced risk of hypotension or arrhythmias.

Protective effect of K(ATP) openers in ischemic rat hearts treated with a potassium cardioplegic solution.

ATP-sensitive potassium channel (KATP) openers directly protect ischemic myocardium, which may make them useful for treating patients undergoing cardiopulmonary bypass, but whether high-potassium-containing cardioplegic solutions would inhibit their protective effects is not clear. We determined whether additional protection greater than that provided by cardioplegia could be found for KATP openers. We studied the effect of 10 microM cromakalim or BMS-180448 pretreatment (10 min before cardioplegia) on severity of ischemia in isolated rat hearts given normothermic or cold St. Thomas' cardioplegic solution (16 mM K+). After cardioplegic arrest, the hearts were subjected to 30-min (normothermic) or 150-min (hypothermic) global ischemia, each followed by 30-min reperfusion. The cardioplegic solutions significantly protected the hearts, as measured by increased time to onset of contracture, enhanced recovery of function, and reduced lactate dehydrogenase (LDH) release. Cromakalim and BMS-180448 both further significantly increased time to contracture in both normothermic and hypothermic arrested hearts; this was accompanied by enhanced recovery of reperfusion contractile function and reduced cumulative LDH release. This additional protective effect of the K ATP openers was abolished by glyburide. Because administration of the K ATP openers only with the cardioplegic solution (1 min before global ischemia) was not efficacious, >1-min pretreatment apparently is necessary. K ATP openers provide additional protection to that afforded by cold or normothermic potassium cardioplegia in rat heart, although the timing of treatment may be crucial.

Glyburide-reversible cardioprotective effect of BMS-180448 is independent of action potential shortening.

OBJECTIVE: We determine if action potential duration (APD) shortening and cardioprotection are separable phenomena in ATP-sensitive potassium channel (KATP) openers which protect ischemic myocardium via a glyburide-reversible mechanism. METHODS: We determined the effect of the weakly vasodilating KATP opener, BMS-180448, and the less cardiac-selective cromakalim, on APD in normal, hypoxic or ischemic guinea pig papillary muscles or isolated hearts and compared their APD effects with their cardioprotective activity in isolated guinea pig hearts. RESULTS: In isolated ischemic guinea pig hearts, cromakalim and BMS-180448 had similar cardioprotective potencies (EC25 of 3.2 and 3.3 microM, respectively, for increasing time to the onset of contracture). At 10 microM, BMS-180448 produced no APD shortening, yet was equally protective at this concentration compared to cromakalim, which produced profound APD shortening under either hypoxic or ischemic conditions. The cardioprotective effects of both compounds at 10 microM were abolished by 0.3 microM glyburide. CONCLUSIONS: APD shortening is not correlated with cardioprotective activity for BMS-180448 and cromakalim while their cardioprotective effects are abolished by glyburide. These results suggest the possibility of reduced proarrhythmic activity in some KATP openers and that their cardioprotective activity is not associated with sarcolemmal KATP opening.

Cardioselective anti-ischemic ATP-sensitive potassium channel openers. 3. Structure-activity studies on benzopyranyl cyanoguanidines: modification of the cyanoguanidine portion.

Structure-activity relationships for the cyanoguanidine portion of the lead cardiac selective ATP-sensitive potassium channel (KATP) opener (3) are described. The cyanoguanidine moity appears to be optimal since increasing or decreasing the distance between the aniline nitrogen and the pendant aromatic ring attenuates anti-ischemic potency/selectivity. Similarly, unfavorable results are obtained by replacement of the aniline nitrogen with other linkers (CH2, S, O). Replacement of the phenyl ring with a methyl group diminishes cardiac selectivity. Constraining the urea moiety into a benzimidazolone or imidazolone ring retains anti-ischemic potency with significant improvement in cardiac selectivity. As shown by the ratio of vasorelaxant and anti-ischemic potencies, the cardiac selectivity in vitro varies over 3 orders of magnitude. These data are in agreement with previous results indicating that distinct structure-activity relationships exist for the anti-ischemic and vasorelaxant activities. Since the anti-ischemic effects of this series of compounds are abolished by pretreatment with structurally different KATP blockers (glyburide, sodium 5-hydroxydecanoate, meclofenamic acid), the mechanism for the anti-ischemic actions of these compounds still appears to involve the opening of KATP.

Pharmacologic profile of the dihydropyrimidine calcium channel blockers SQ 32,547 and SQ 32,926 [correction of SQ 32,946].

SQ 32,926 and SQ 32,547, two dihydropyrimidine calcium channel blockers, were characterized as potent inhibitors of depolarization-induced contractions of isolated smooth muscle preparations. In rat aorta, the IC50 values were 5.5 nM for SQ 32,547 and 8.1 nM for SQ 32,926, values which compare favorably with that of 2.9 nM for nifedipine. The dihydropyrimidines were also tested in a model of stable angina: pacing-induced ischemia in dogs. Both SQ 32,547 and SQ 32,926 reduced the ST-segment elevation observed in vehicle-treated animals. No significant changes in hemodynamic status were detected, suggesting that a reduction in cardiac work secondary to afterload reduction was probably not a major contributor to the protective effects. Neither was increased coronary blood flow important for the antiischemic outcome because no significant effects of the dihydropyrimidines were observed on ischemic regional blood flow. SQ 32,547 was also studied in globally ischemic, isolated rat hearts. In this model, SQ 32,547 was protective because it significantly reduced contracture formation and lactate dehydrogenase (LDH) release. Washing out the effect of SQ 32,547 in isolated hearts and smooth muscles was difficult, presumably due to its lipophilicity. In the smooth muscle preparations, the effects of both nifedipine and SQ 32,926 were much more easily washed out. As with other calcium channel blockers, increasing the antiischemic effects of SQ 32,547 was associated with a higher cost in terms of cardiac function. In summary, the two novel dihydropyrimidines, SQ 32,547 and SQ 32,926 showed antiischemic properties in animal models.

Cardioselective antiischemic ATP-sensitive potassium channel openers. 2. Structure-activity studies on benzopyranylcyanoguanidines: modification of the benzopyran ring.

The ATP-sensitive potassium channel (KATP) openers are of considerable interest as myocardial protecting agents. However, there exists a narrow window of safety for the use of first-generation compounds as antiischemic agents due to their powerful peripheral vasodilating effects, which can result in underperfusion of the area already at risk. We have recently disclosed the discovery of benzopyranylcyanoguanidine type KATP openers (BMS-180448) which are more selective for the ischemic myocardium compared to the first-generation compounds. This publication deals with structure-activity relationships for the antiischemic activity of the lead compound 8. The presence of an electron-withdrawing group at C6, an sp3 center at C4, and a gem-dimethyl group at C2 appears to be essential for antiischemic activity. Cyanoguanidine can be replaced with a urea moiety. The results reported here support the hypothesis that distinct structure-activity relationships exist for antiischemic and vasorelaxant activities of compounds related to 8 and cromakalim. The trifluoromethyl analog 10 is 550-fold more selective in vitro for the ischemic myocardium compared to the first-generation agent cromakalim. The reasons for the selectivity of these compounds for the ischemic myocardium are not clear at the present time. They may be related to the existence of receptor subtypes in smooth muscle and the myocardium.

In vitro effects of capsaicin: antiarrhythmic and antiischemic activity.

The antiarrhythmic effects of vehicle (0.1% dimethyl sulfoxide: DMSO) or capsaicin were evaluated in isolated perfused rat and guinea pig heart preparations. In the rat, capsaicin reduced ischemic ventricular tachycardia from 100% in control to 0%, and ischemic ventricular fibrillation from 60% in control to 0% at 30 microM, and diltiazem reduced the incidence of ischemic ventricular tachycardia and ventricular fibrillation to 55% and 0%, respectively. Reperfusion ventricular fibrillation was reduced from 90% to 20% and 33% for capsaicin and diltiazem, respectively, at these concentrations. In isolated perfused globally ischemic rat hearts, antiischemic efficacy was assessed as a significant extension (36% and 50%) in time to contracture with 30 microM capsaicin and 1 microM diltiazem, respectively. Capsaicin reduced left ventricular developed pressure by 35% in non-ischemic rat hearts, and increased coronary flow by 40%. The increased time to contracture for either compound was not blocked by glyburide (0.1 microM) suggesting a lack of any involvement of ATP-sensitive K+ channels. In isolated guinea pig hearts subjected to global ischemia, capsaicin and diltiazem reduced reperfusion ventricular fibrillation from 100% to 10% and 0% at 30 and 3 microM, respectively. Electrophysiologic evaluation in guinea pig papillary muscles using standard microelectrode techniques demonstrated significant (P < 0.05) action potential durations at 90% repolarization shortening at 1 Hz by 9%, 28% and 39%, and 23%, 37% and 51% at 10, 30, and 100 microM of capsaicin or diltiazem, respectively. Unlike diltiazem, no changes in action potential duration were observed with capsaicin (up to 100 microM) at faster stimulation rates (5 Hz). In conclusion, capsaicin displays both antiarrhythmic and antiischemic efficacy. These data suggest that the effects of capsaicin are mediated primarily through block of Ca2+ channels in these preparations.

Endogenous catecholamines are not necessary for ischaemic preconditioning in the isolated perfused rat heart.

OBJECTIVE: The mechanism of the protective effect of ischaemic preconditioning in the myocardium is not yet known. The aim of this study was to test the hypothesis that endogenous myocardial catecholamines may be mediators of preconditioning. METHODS: To test whether endogenous catecholamines are involved in preconditioning, experiments were performed in hearts from rats which had been catecholamine depleted with either reserpine or 6-hydroxydopamine. Experiments were also done to determine if noradrenaline can mimic preconditioning. RESULTS: Catecholamine depletion with either reserpine or 6-hydroxydopamine had no effect on preischaemic coronary flow or cardiac function. Ischaemic preconditioning (four episodes of 5 min global ischaemia and 5 min reperfusion) resulted in a significant increase in postischaemic cardiac function and a 50% decrease in lactate dehydrogenase (LDH) release following 30 min ischaemia and 30 min reperfusion compared with non-preconditioned hearts. Reserpine pretreatment did not affect the response to ischaemia or to preconditioning, although LDH release tended to be greater than in normal hearts, especially in the non-preconditioned group. Although 6-hydroxydopamine significantly increased postischaemic cardiac function in the preconditioned group, no other index of ischaemic damage (for example, LDH release, left ventricular end diastolic pressure) was affected. Further studies showed that 10 nmol.min-1 noradrenaline did not affect the severity of ischaemia, indicating that it does not mimic preconditioning. CONCLUSIONS: Endogenous catecholamines are not necessary for ischaemic preconditioning in isolated rat hearts and play little or no role in the functional responses to ischaemia.

Effect of potassium on the action of the KATP modulators cromakalim, pinacidil, or glibenclamide on arrhythmias in isolated perfused rat heart subjected to regional ischaemia.

OBJECTIVE: The ATP sensitive potassium channel openers cromakalim (n = 10) and pinacidil (n = 10), and a blocker of this channel, glibenclamide (n = 10), were studied in isolated perfused rat hearts subjected to regional ischaemia at varying concentrations (2 to 8 mM) of external potassium ([K+]o). METHODS: Hearts were isolated and perfused on a Langendorff apparatus. Vehicle (0.1% DMSO), cromakalim (10 microM), pinacidil (10 microM), or glibenclamide (10 microM) were given 10 min before ischaemia. The left coronary artery was then occluded for 15 min and reperfused for 5 min. RESULTS: No agent caused more than a 10% change in heart rate. Both cromakalim and pinacidil increased (30%), and glibenclamide decreased (30%) coronary flow at 4 and 6 mM [K+]o. In the vehicle group, increases in [K+]o produced concentration dependent reductions in arrhythmia scores by decreasing ventricular fibrillation. No concentration dependent effects of [K+]o on ischaemic ventricular tachycardia was observed. Under ischaemic conditions, potassium channel openers and glibenclamide more markedly reduced ischaemic ventricular tachycardia and fibrillation relative to the effects of increased [K+]o. CONCLUSIONS: Ischaemic ventricular fibrillation was inversely related to changes in [K+]o, whereas effects on ventricular tachycardia were all-or-none. Neither potassium channel openers nor glibenclamide elicited significant proarrhythmic activity despite variations in [K+]o. These data suggest that both potassium channel openers and glibenclamide display potential antiarrhythmic activity through their ability to abolish two distinct arrhythmogenic mechanisms during ischaemia. It is also suggested that the underlying mechanisms of ventricular tachycardia and fibrillation are coupled during ischaemia in the rat.

The cardioprotective and electrophysiological effects of cromakalim are attenuated by meclofenamate through a cyclooxygenase-independent mechanism.

Recent published studies indicate that the cyclooxygenase inhibitor meclofenamate can abolish preconditioning. Unpublished preliminary data from this laboratory suggest that meclofenamate may be blocking cardiac ATP-sensitive potassium channels (KATP channels), which may also mediate preconditioning. The purpose of the present study was to determine whether meclofenamate is a cardiac KATP channel blocker and it can abolish the anti-ischemic activity of the KATP channel opener cromakalim. This concept was tested initially in an isolated rat heart model of 25 min of ischemia and 30 min of reperfusion. Meclofenamate, in a concentration (5 microM) that did not cause proischemic effects alone, abolished the protective effect of cromakalim, as measured by recovery of contractile function, lactate dehydrogenase release and contracture formation. The preischemic coronary dilating activity of cromakalim was not attenuated by meclofenamate. The cyclooxygenase inhibitors indomethacin and SQ 29,109 had no effect on the cardioprotection afforded by cromakalim. Concentration-response curves for the ability of cromakalim to increase time to contracture during ischemia in rat hearts were generated alone or in the presence of 5 or 10 microM meclofenamate. Cromakalim increased the time to contracture with an EC25 of approximately 3 microM. Meclofenamate appeared to block this effect in a manner that was not surmountable by 100 microM cromakalim. Studies in guinea pig hearts showed that meclofenamate had no effect on action potential duration or effective refractory period when given alone. Meclofenamate attenuated the action potential duration shortening effects of cromakalim in this model. Thus, meclofenamate blocked the cardioprotective effects of cromakalim and this effect was not related to cyclooxygenase inhibition. Meclofenamate appears to be a cardiac KATP channel blocker.