Charles S. Parham

Pharmacologic profile of the dihydropyrimidine calcium channel blockers SQ 32,547 and 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.

Cardioprotection with the KATP opener cromakalim is not correlated with ischemic myocardial action potential duration.

Summary: We endeavored to determine if the enhanced shortening of the myocardial action potential duration (APD) during ischemia can be dissociated from the cardioprotective effects of the adenosine triphosphate (ATP) sensitive potassium channel (KATP) opener cromakalim. To establish if there is a relationship between APD shortening and the cardioprotective effect of cromakalim, we determined the effect of a dose of the delayed rectifier (IKr) blocker dofetilide (which abolishes the APD shortening effect of cromakalim) on the cardioprotective activity of cromakalim. Cromakalim was infused at a previously determined cardioprotective dose (10 μg/kg + 0.3 μg/kg/min infusion i.c.), and we determined the effect of 1 mg/kg (followed by a 0.01 mg/kg/min i.v. infusion) dofetilide alone and in combination with cromakalim on APD shortening and infarct size (90-min coronary occlusion and 5-h reperfusion) in anesthetized dogs. Dofetilide completely abolished the APD shortening effects of cromakalim during ischemia such that APD was similar to preischemic values. Cromakalim only shortened the APD during ischemia, although this effect was attenuated late into ischemia. Cromakalim significantly reduced infarct size (40% reduction from vehicle group value), whereas dofetilide alone had no effect. Dofetilide, at a dose that prevented the cromakalim-induced shortening of APD in ischemic tissue, did not attenuate the cardioprotective effects of cromakalim. No differences in collateral blood flow for any of the groups were observed. Dofetilide did cause a slight bradycardia, but this effect is unlikely to affect the interpretation of the results. These data suggest that APD shortening observed with the KATP opener cromakalim is not correlated with its cardioprotective effects.

The protective effects of cromakalim and pinacidil on reperfusion function and infarct size in isolated perfused rat hearts and anesthetized dogs.

SummaryThe direct myocardial protective effects of intracoronary infusions of cromakalim and pinacidil were determined in an anesthetized canine model of coronary occlusion and reperfusion. The left circumflex coronary artery was occluded for 90 minutes and reperfused for 5 hours, at which time the infarct size was determined. Cromakalim (0.1 μg/kg/min) or pinacidil (0.09 μg/kg/min) were infused into the left circumflex coronary artery starting 10 minutes preischemia. Cromakalim significantly reduced infarct size as a percent of the left ventricular area at risk (25±5%) compared with vehicle controls (55±7%). Pinacidil did not reduce infarct size at an equimolar dose, but at the higher dose also significantly reduced infarct size. Collateral blood flow was not significantly altered by either drug, though reperfusion flow was significantly higher in cromakalim-treated animals, particularly in the subepicardial region. When the same dose of cromakalim was given starting 2 minutes before the initiation of reperfusion, no significant beneficial effect of cromakalim was observed. In another study, isolated buffer-perfused rat hearts were subjected to 25 minutes of global ischemia and 30 minutes of reperfusion. These hearts were treated with 7 μM cromakalim, either starting 10 minutes before ischemia or only during reperfusion, and its effect on reperfusion function and LDH release were determined. Cromakalim pretreatment (both when given throughout the experiment and when not present in the reperfusion buffer) resulted in significant improvements in the reperfusion function. Reperfusion contracture and LDH were also significantly reduced with this treatment. When given only during reperfusion, cromakalim did not reduce the severity of ischemia when compared with vehicle controls. Thus, both cromakalim and pinacidil reduce ischemic/reperfusion injury, though the timing of treatment may be important.

Nicorandil improves postischemic contractile function independently of direct myocardial effects

We determined whether any of the antiischemic effects of nicorandil were due to direct cardioprotective effects such as potassium channel activation or to its peripheral hemodynamic effects. Nicorandil was administered either intravenously (i.v.) or directly into the ischemic coronary artery (i.c.) and compared with i.c. cromakalim (a potassium channel activator previously shown to improve reperfusion function directly in rat hearts) or vehicle for their ability to improve postischemic contractile function as measured by ultrasonic crystals in anesthetized dogs or in isolated perfused rat hearts. In a model of 25-min global ischemia and reperfusion in isolated perfused rat hearts, nicorandil (10–100 μM) did not improve reperfusion function or decrease LDH re-lease, although 300 μM nicorandil did protect the hearts. Cromakalim (7 μM)significantly improved reperfusion function and reduced lactate dehydrogenase (LDH) re-lease. In the dog studies, the left anterior descending coronary artery (LAD) was occluded for 15 min and was reperfused for 3 h. Nicorandil improved reperfusion function only when administered i.v., although i.c. cromakalim was efficacious in improving function. Neither nicorandil nor cromakalim improved collateral flow, although cromakalim significantly improved preischemic and reperfusion blood flows, particularly in the subepicardial region. Although i.c. treatment with cromakalim and nicorandil did not result in significant changes in peripheral hemodynamic status, i.v. nicorandil reduced both preload and afterload. Thus, at the dose used, nicorandil does not appear to have direct myocardial protective effects and the beneficial effects of nicorandil do not appear to be related to potassium channel activation in the myocardium. Potassium channel activation by cromakalim does result in direct cardioprotective effects whereas nicorandil appears to be dependent on peripheral actions for its efficacy.

The cardioprotective effects of the thromboxane receptor antagonist SQ 30,741 are not reversed by aspirin

SummaryA previous study indicated that 5 mg/kg aspirin can reverse the cardioprotective effects of thromboxane A2 synthetase inhibitors. We determined in the present study if this dose of aspirin can also reverse the protective effects of the thromboxane A2/PGH2 receptor antagonist SQ 30,741 in the same model of coronary occlusion and reperfusion. Anesthetized dogs were subjected to 90 min of coronary occlusion and 5 h of reperfusion and were treated with vehicle or SQ 30,741 (1 mg/kg + 1 mg/kg/h) 10 min after the onset of coronary occlusion. SQ 30,741 was given to dogs pretreated with aspirin (5 mg/kg, 24 h presurgery) or vehicle. SQ 30,741 significantly reduced infarct size compared to vehicle treatment (58 % vs 35 % of the left ventricular area at risk for vehicle and SQ 30,741 groups respectively) and aspirin did not reverse this. These anti-ischemic effects occurred despite a lack of change in collateral flow. Thus, important differences in mechanism of action between thromboxane synthesis inhibitors and receptor antagonists seem to exist and further work in this area is warranted.

Protective Effect of Mitochondrial Katp Activation in an Isolated Gracilis Model of Ischemia and Reperfusion in Dogs

Adenosine triphosphate–sensitive potassium channel (KATP) openers protect ischemic myocardium by direct protection of cardiac myocytes, which is thought to be a result of activation of mitochondrial KATP (mKATP). KATP is expressed in skeletal muscle, and the purpose of this study was to determine the effect of the mKATP opener BMS-191095 on infarct size in an isolated gracilis model of ischemia and reperfusion in dogs. The right and left gracilis muscles were isolated in anesthetized dogs except for the artery and vein supplying these muscles (pedicle). BMS-191095 (0.4 mg) or vehicle were infused directly into the artery supplying each gracilis muscle (each animal had one drug-treated and one vehicle-treated muscle). The pedicle was completely occluded for 5 hours followed by 48 hours of reperfusion, after which infarct size was determined. In the vehicle-treated gracilis muscles, significant necrosis was observed (82% ± 3% of gracilis muscle). BMS-191095 significantly reduced the infarct size in the contralateral gracilis muscle (55% ± 6%). Reflow into the gracilis muscle was significantly greater in BMS-191095–treated muscles. BMS-191095 appears to reduce damage in ischemic/reperfused skeletal muscle, suggesting that mKATP activation is an important protective mechanism in this tissue.

Anti-ischemic activity of the novel benzazepine calcium antagonist SQ 31,486

We tested the benzazepine, SQ 31,486 for its ability to selectively block the voltage-dependent calcium channel and to protect the ischemic myocardium. SQ 31,486 was found to be a selective calcium antagonist in vascular tissue with an IC50 value of 1.5 μM in KCI-contracted rabbit aorta. SQ 31,486 decreased contractile function and increased coronary flow in nonischemic isolated rat hearts in a concentration-dependent manner. SQ 31,486 also significantly reduced postischemic lactate dehydrogenase (LDH) release and end-diastolic pressure (EDP) compared to vehicle. Reperfusion double product [heart rate (HR) X left ventricular developed pressure (LVDP)] was also significantly improved by SQ 31,486. Diltiazem was a less potent anti-ischemic agent and was significantly more cardiodepressant relative to its antiischemic efficacy than was SQ 31,486. Thus, SQ 31,486 should have a larger therapeutic index. In a model of pacing-induced myocardial ischemia in anesthetized, open chest dogs, SQ 31,486 reduced pacing-induced ST-segment elevation ∼50% at 10, 40, and 70 min after drug administration. This protective effect occurred despite a lack of effect of SQ 31,486 on ischemic regional blood flow and peripheral hemodynamic status.

The effect of the thromboxane A2/prostaglandin endoperoxide receptor antagonist SQ 30,741 on myocardial infarct size and blood flow during myocardial ischemia and reperfusion

Summary: The effect of the thromboxane A2 (TXA2) receptor antagonist SQ 30,741 on infarct size and myocardial blood How during coronary occlusion and reperfusion was determined. In anesthetized dogs, the left circumflex coronary artery (LCX) was occluded and after 10 min a continuous infusion of SQ 30.741 (1 mg/kg + 1 mg/kg/h, i.v.) or saline was begun. After 90 min of LCX occlusion, the LCX was reperfused for 5 h and infarct size was then determined. Myocardial blood flows before. during, and after occlusion were determined using radioactive microspheres. SQ 30,741 resulted in a significant decrease in infarct size (34% + 6% of left ventricular area at risk) compared to controls (60% ± 9%). Cardioprotection was also found with SQ 30,741 when infarct size was normalized for both area at risk and predrug collateral How. The protective effect of SQ 30,741 occurred without an increase in collateral flow. At 1h postreperfusion, subendocardial flow was significantly higher in SQ 30,741-treated animals (109 ± 15 ml/min/100 g) compared to controls (71 ± 16 ml/min/100g). SQ 30,741. in the dose resulting in infarct size reduction, produced a 95% inhibition of platelet TXA2 receptors throughout the experiment as measured by dose-dependent inhibition of the ex vivo platelet shape change response to U-46.619. a TXA2 mimetic. Thus, a dose of SQ 30,741 that results in TXA2 blockade also results in myocardial salvage without changes in collateral flow.

The role of thromboxane A2 in reperfusion injury.

Abstract Thromboxane A2 (TXA2) receptor antagonists can limit infarct size in models of coronary occlusion and reperfusion, but it was unknown if these compounds can mitigate reperfusion injury. Anesthetized open chest dogs were subjected to left circumflex coronary (LCX) occlusion for 90 min. Two minutes before reperfusion, the dogs were given iv saline (0.9% NaCl) or the TXA2 antagonist SQ 29,548 (0.2 mg/kg + 0.2 mg/kg/hr). Reperfusion was instituted for 5 hr at which time infarct size was determined. Regional myocardial blood flow was determined before, during, and after occlusion. SQ 29,548 treatment resulted in a significant reduction in infarct size (57 ± 7 and 34 ± 8% of the left ventricular area at risk infarcted in the saline and SQ 29,548 groups, respectively). No differences in collateral flow during occlusion were observed between groups, but SQ 29,548 treatment resulted in a significantly higher subendocardial reperfusion flow (54 ± 10 and 93 ± 14 ml/min/100g for the saline and SQ 29,548 groups, respectively). Thus, TXA2 seems to play a role in exacerbating reperfusion injury and TXA2 receptor blockade may have potential as a mode of therapy for ischemia-reperfusion damage.

Effect of intracoronary diltiazem on ST-segment elevation and myocardial blood flow during pacing-induced ischemia.

Summary This study was performed to determine if diltiazem can reduce the severity of pacing-induced ischemia independently of its peripheral hemodynamic effects and of increases in ischemic region blood flow. Twelve anesthetized dogs were subjected to atrial pacing and had their left anterior descending coronary arteries (LAD) occluded gradually until ischemia ensued (>10 mV epicardial ST-segment elevation). Cessation of pacing resulted in abolition of ST-segment elevation. ST-segment elevation, as well as peripheral and coronary hemodynamics, was measured during 5-min periods of pacing + LAD stenosis before and 0.30, and 60 min after-treatment with intracoronary (just distal to the stenosis) saline or 1.8 μg/kg diltiazem. Myocardial blood flow was measured using radioactive microspheres during pacing, pacing + stenosis, and pacing + stenosis + drug treatment at 60 min. Diltiazem significantly reduced ST-segment elevation 50% at 0.30, and 60 min compared with elevations seen in animals treated with saline as well as predrug values. No changes in blood pressure, heart rate, or LAD flow occurred with diltiazem. Overall ischemic tissue How and its transmural distribution were not different with diltiazem compared with saline treatment. Thus, diltiazem can decrease the severity of pacing-induced ischemia independently of its peripheral effects and of increased ischemic region blood flow.