Dose-related kinetics of aspirin. Presystemic acetylation of platelet cyclooxygenase

Effects of early intervention with low-dose aspirin (100 mg) on infarct size, reinfarction and mortality in anterior wall acute myocardial infarction

Recently, it was shown that aspirin given early in acute myocardial infarction (AMI) improves hospital survival, but the mechanisms involved are unclear. In a prospective, randomized placebo-controlled trial, the influence of early intervention with low-dose aspirin (100 mg/day) on infarct size and clinical outcome was studied in 100 consecutive patients with first anterior wall AMI. Infarct size was calculated by cumulative lactate dehydrogenase release in the first 72 hours after admission and was found to be (mean +/- standard deviation) 1,431 +/- 782 U/liter in the aspirin group (n = 50) and 1,592 +/- 1,082 U/liter in the placebo group (n = 50, p = 0.35). The study medication was given for 3 months, during which mortality was 10 (20%) in the aspirin patients and 12 (24%) in the placebo patients (p = 0.65). However, reinfarction occurred in 2 patients (4%) in the aspirin group and in 9 (18%) in the placebo group (p less than 0.03). Early intervention with low-dose aspirin showed, in comparison to placebo, a 10% decrease of infarct size, but this difference was not statistically significant. However, early low-dose aspirin effectively decreased the risk of reinfarction. Therefore, the favor able results of early aspirin on mortality in acute myocardial infarction are probably due more to prevention of reinfarction than to decrease of infarct size.

Doppler ultrasound and aspirin in recognition and prevention of pregnancy-induced hypertension

Screening of 1226 nulliparous women by means of doppler uteroplacental flow-velocity waveforms in early pregnancy identified 148 (12%) as being at high risk of pregnancy-induced hypertension. After exclusions and refusals, 100 women were randomly allocated to groups receiving either low-dose aspirin (75 mg daily; 48 patients) or identical placebo (52 patients) for the remainder of the pregnancy. The difference between the aspirin and placebo groups in the frequency of pregnancy-induced hypertension (13% vs 25%) did not achieve significance, but there were significant differences in the frequencies of proteinuric hypertension (2% vs 19%) and hypertension occurring before 37 weeks' gestation (0% vs 17%). Fewer aspirin-treated than placebo-treated women had low birthweight babies (15% vs 25%), but this difference was not significant. The only perinatal death in the aspirin group followed a cord accident during labour, whereas the 3 perinatal deaths in the placebo group were all due to severe hypertensive disease. No maternal or neonatal side-effects were observed in either group.

Current concepts for a drug-induced inhibition of formation and action of thromboxane A2

Urinary and plasma metabolites of thromboxane A2 (TxA2) indicate an increased TxA2 synthesis in a number of diseases, whereby TxA2 is assumed to contribute to the underlying pathomechanisms by its profound effects on platelet aggregation and smooth muscle contraction. In some clinical situations the increment in TxA2 biosynthesis is accompanied by an increased formation of prostacyclin (PGI2) which is one of the most potent inhibitors of platelet activation and smooth muscle contraction. Therefore, drugs are being developed which suppress the formation or action of TxA2 without interfering with its functional antagonist PGI2. Low doses of acetylsalicyclic acid (ASA) preferentially inhibit cyclooxygenase activity in platelets and the synthesis of TxA2 in vivo. However, neither low doses (approximately 300 mg/day) nor very low doses spare the formation of PGI2 completely. Despite its limited selectivity, very low dose ASA (approximately 40 mg/day) provides an attractive perspective in TxA2 pharmacology. Although thromboxane synthase inhibitors selectively suppress TxA2 biosynthesis PGH2 can accumulate instead of TxA2 and substitute for TxA2 at their common TxA2/PGH2 receptors. Thromboxane synthase inhibitors can only exert platelet-inhibiting and vasodilating effects if PGH2 rapidly isomerizes to functional antagonists like PGI2 that can be formed from platelet-derived PGH2 by the vessel wall. TxA2/PGH2 receptor antagonists provide a specific and effective approach for inhibition of TxA2. These inhibitors do not interfere with the synthesis of PGI2 and other prostanoids but prevent TxA2 and PGH2 from activating platelets and inducing smooth muscle contractions. Most of the available TxA2/PGH2 receptor antagonists produce a competitive antagonism that can be overcome by high agonist concentrations. Since in certain disease states very high local TxA2 concentrations are to be antagonized, non-competitive receptor antagonists may be of particular interest. Some recent TxA2/PGH2 receptor antagonists produce such a non-competitive type of inhibition due to their low dissociation rate constant. As a consequence, agonists like TxA2 or PGH2 only reach a hemiequilibrium state at their receptors, previously occupied by those antagonists. A combination of a thromboxane synthase inhibitor with a TxA2/PGH2 receptor antagonist presents a very high inhibitory potential that utilizes the dual activities of the synthase inhibitor to increase PGI2 formation and of the receptor antagonist to antagonize PGH2 and TxA2. Such combinations or dual inhibitors, combining both moieties in one compound, prolong the skin bleeding time to a greater extent than thromboxane synthase inhibitors and even more than low dose ASA or TxA2/PGH2 receptor antagonists.

Effect of salicylates on antibiotic sensitivity

The effect of sodium salicylate (SA) or acetylsalicylate (ASA) on sensitivity to two different antibiotics on porin-deficient Gram-negative bacteria was investigated. Neither SA nor ASA nor any combinations of the two drugs within the therapeutic range altered minimum inhibitory concentrations (MICs) or minimum bactericidal concentrations (MBCs) of mezlocillin and ciprofloxacin against Pseudomonas aeruginosa, Serratia marcescens and Proteus vulgaris strains. It is concluded that SA and ASA do not seem to interfere with antimicrobial therapy of Gram-negative porin deficient bacteria.

Acetylsalicylic acid and the balance between prostacyclin and thromboxane A2

Arachidonic acid is metabolized in endothelial cells to antiaggregatory, vasodilatory prostacyclin (PGI2), and in platelets to aggregatory, vasoconstrictory thromboxane A2 (TxA2). The balance of these two prostanoids is supposed to be involved with thrombogenesis and atherogenesis. Acetylsalicylic acid (ASA) inhibits irreversibly the key enzyme of the synthesis of these prostanoids, i.e. cyclo-oxygenase. Platelets do not synthetize new protein, but endothelial cells do. Because of this, and certain pharmacokinetic characteristics of ASA, it should be possible to shift the balance between PGI2 and TxA2 to the dominance of the former with the proper dose of this drug. Altogether more than 50,000 subjects have volunteered for studies on the effect of ASA in the primary or secondary prevention of myocardial infarction or ischemic stroke. The results show that it is possible to reduce vascular attacks by ASA. Furthermore, ASA has also found to prevent pre-eclampsia. Conclusions on the effect of ASA on the PGI2/TxA2-balance are hampered by uncertainties concerning the measurement PGI2 and TxA2 productions in vivo. It is, however, evident that the doses of ASA used in most trials have been high enough to inhibit partly also the production of PGI2. Whether smaller doses or less frequent administration would be more efficient, remains to be studied.

Low dose ASA (4 mg/kg) peroperatively does not prevent in vivo platelet accumulation at microarterial anastomotic sites. An experimental study in the rabbit

Twenty microarterial end-to-end anastomoses were performed on the central arteries of the ears in 12 rabbits divided into two groups: Group A (10 anastomoses) served as control and Group B (10 anastomoses) was treated with 4 mg ASA per kg b.w. given as a single intraaortical dose 5 min prior to infusion of 32P-labelled platelets. Two hours later blood-flow was reestablished after end-to-end anastomoses. Anastomotic bleeding-times, qualitative and quantitative differences in platelet accumulation and patency were registered. In addition, platelet aggregability and thromboxane production were studied in 3 rabbits. The bleeding-times (median and quartiles) in group A were 3(+0)-2 min and in group B 3(+2)-0 min. In vivo accumulation of 32P-labelled platelets was somewhat increased initially (p less than 0.05) in the ASA group. Poor patency was registered in two vessels, one in each group, all other vessels having good patency. Aspirin peroperatively in low doses (4 mg/kg) did not markedly affect bleeding-times or patency rates in microarterial anastomoses, but platelet accumulation in vivo was initially increased. The radioactivity values decreased with time in all aspirin cases but only in 50% of the control group vessels, suggesting efficient platelet disaggregation/fibrinolysis. This might favour the view that PGI2 production in the endothelium recovers more rapidly than the pro-aggregatory mechanisms affected by ASA. ASA-treatment led to almost complete inhibition of thromboxane production for at least four hours, but, despite this, a moderate decrease in platelet aggregability occurred only when collagen was used as stimulant.

Metabolism of drugs and other xenobiotics in the gut lumen and wall

Metabolism in the gut lumen and wall can decrease the bioavailability and the pharmacological effects of a wide variety of drugs. Bacterial flora in the gut, the environmental pH and oxidative or conjugative enzymes present in the intestinal epithelial cells can all contribute to the process. Bacterial biotransformation is greatest in the colon, while gut wall metabolism is generally highest in the jejunum and decreases distally. Gut wall metabolism may be induced or inhibited by dietary or environmental xenobiotics or by co-administered drugs. Recent evidence suggests that some drugs, food-derived mutagens and other xenobiotics can be metabolized by gut flora and/or gut wall enzymes to reactive species which may cause tumors.

Superior antiplatelet action of alternate day pulsed dosing versus split dose administration of aspirin

To explore the effect of timing on the antiplatelet action of aspirin, a constant mean amount of 40 mg aspirin/day was administered either as a split regimen of 20 mg twice daily, a single dose of 40 mg or a doubled dose of 80 mg every other day for 1 week each and compared to a current standard low dose regimen of 324 mg/day. Bleeding time, serum thromboxane, collagen-stimulated platelet aggregation and associated thromboxane formation and excretion of thromboxane and prostacyclin metabolites were measured both at peak and trough action of the drug. The inhibitory effects on platelet aggregation and associated thromboxane formation were significantly less marked with the split dose regimen, intermediate with the single dose of 40 mg aspirin/day and best with the alternate day doubled dose, but still inferior to the effects of 324 mg/day. Thromboxane excretion was suppressed by greater than 80% with all regimens. Prostacyclin metabolite excretion was similar for all 40 mg/day regimens with about 40% suppression at trough and 60% at peak drug action, respectively. Suppression was more pronounced after 324 mg/day. For best platelet inactivation at comparable sparing of prostacyclin formation, low doses of aspirin should be administered in pulsed rather than split regimens.

Enhanced gastric mucosal bleeding with doses of aspirin used for prophylaxis and its reduction by ranitidine

1. We evaluated injury to the human gastric mucosa caused by low doses of aspirin and its prophylaxis by ranitidine. On two separate occasions, 30 subjects took aspirin 300 mg daily for 12 days either with or without ranitidine 150 mg, 30 min before aspirin. This dose of aspirin caused more than a 5 fold increase in gastric bleeding, from control values of 0.5 microliters 10 min-1 (95% confidence limits 0.3-0.8 microliters 10 min-1) to 2.8 microliters 10 min-1 (1.9-4.1 microliters 10 min-1, P less than 0.01) after 5 days of aspirin. Adaptation did not occur and the gastric bleeding rates remained elevated at 3.4 microliters 10 min-1 (1.9-6.1 microliters 10 min-1) after 12 days of aspirin consumption (P less than 0.01). 2. Coadministration of ranitidine significantly raised intragastric pH and reduced aspirin induced bleeding to 1.5 microliters 10 min-1 (1.0-2.3 microliters 10 min-1) after 5 days and 1.6 (1.0-2.5 microliters 10 min-1) after 12 days (P less than 0.05). 3. Although these values were higher than control levels our results raise the possibility that coadministration of ranitidine may reduce the incidence of peptic ulceration and gastrointestinal haemorrhage which is increasingly reported in some subjects taking low dose aspirin for vascular prophylaxis.

Differential effect of aspirin on thromboxane and prostaglandin biosynthesis in man

1. Effects of a single intravenous dose of aspirin (600 mg) on bradykinin-stimulated prostaglandin (PG) and on thromboxane (TX) biosynthesis were determined in nine healthy male volunteers. Plasma concentrations of 6-oxo-PGF1 alpha and 13,14-dihydro-15-oxo-PGF2 alpha were measured in samples obtained during repeated 10 min intravenous infusions of bradykinin before and up to 6 h after the dose of aspirin. TXB2 was measured in serum from blood allowed to clot at 37 degrees C. 2. Aspirin inhibited bradykinin stimulated PG and platelet TX biosynthesis 0.5 h after the dose. Serum TXB2 remained low, whereas PG synthesis recovered within 6 h. 3. Effects of intravenous sodium salicylate (600 mg) were studied identically in eight subjects. Prostanoid biosynthesis was not inhibited. 4. Biosynthesis of prostacyclin and TXA2 under basal conditions was studied in eight subjects by measuring 2,3-dinor-6-oxo-PGF1 alpha and 2,3-dinor-TXB2 in hourly urine samples obtained during and after intravenous infusion of aspirin and, on a separate occasion, of vehicle. 5. Aspirin infusion reduced urinary excretion of both metabolites greater than 90%, but excretion of 2,3-dinor-6-oxo-PGF1 alpha recovered more rapidly than did that of 2,3-dinor-TXB2. 6. We conclude that cyclo-oxygenase is rapidly synthesised in bradykinin-responsive tissues in vivo and that this reflects similarly rapid enzyme biosynthesis in tissues that produce PGI2 under basal conditions.

Effects of aspirin and prostaglandin E1 on in vitro thrombolysis with urokinase. Evidence for a possible role of inhibiting platelet activity in thrombolysis

The formation of thrombi in vivo includes the activation of both platelets and the coagulation cascade. Conventional thrombolytic therapy is primarily directed toward the dissolution of fibrin. To evaluate the possibility that platelet activity impairs the lysis of thrombi, we studied the effects of aspirin and platelet-deaggregating prostaglandin E1 on thrombolysis with urokinase. Combined platelet and fibrin thrombi were produced in vitro by adding CaCl2 and collagen (1 microgram/ml) to citrated platelet-rich plasma (250,000 platelets per microliters). Urokinase (500-10,000 units/ml) caused a dose-dependent weight loss of the thrombi that was maximal at 2,000 units/ml. The addition of aspirin (10-200 micrograms/ml) to platelet-rich plasma before thrombus formation markedly enhanced thrombolysis with urokinase. This effect was most pronounced at 20 micrograms/ml aspirin. However, when aspirin was added after completion of thrombus formation, no significant effect on thrombolysis was noted. Prostaglandin E1 (1-100 mumol/l) improved the lysis with urokinase of the combined platelet and fibrin thrombi. This effect was maximal at 20 mumol/l prostaglandin E1. When pure fibrin thrombi were produced in platelet-free plasma, prostaglandin E1 was without effect on lysis. Thus, in vitro lysis with urokinase of combined platelet and fibrin thrombi was enhanced by the addition of platelet-deaggregating prostaglandin E1 and by pretreatment with aspirin.

Aspirin and thymosin increase interleukin-2 and interferon-gamma production by human peripheral blood lymphocytes

Interleukin-2 (IL-2) and interferon-gamma (IFN-gamma) have recently been added to the arsenal of synthetic biological response modifiers with important immunomodulatory activities. In this paper we have assessed the effects of acetylsalicylic acid (aspirin), thymosin alpha and thymosin fraction 5 (TF5), a partially purified calf thymic preparation, on production of IFN-gamma in vitro. Stimulation by oral aspirin of IL-2 and IFN-gamma production by peripheral blood lymphocytes (PBLs) was also studied in healthy human volunteers. Aspirin, thymosin alpha 1 and TF5 were all observed to enhance phytohemagglutinin (PHA)-stimulated production of IFN-gamma. Peak IFN-gamma production by PHA-stimulated PBLs was observed after 24 h of incubation with TF5 and after 72 h with aspirin. Stimulation by aspirin and TF5 required the presence of macrophages, and was additive and dose-dependent. The additive effects of aspirin and TF5 suggest that these agents act by different mechanisms. Oral administration of aspirin in normal volunteers significantly enhanced production of both IFN-gamma and IL-2. PHA-stimulated IFN-gamma production was greatest 24 h after aspirin ingestion; in contrast, IL-2 production was optimal 10 h after aspirin ingestion. These observations suggest that oral aspirin is an effective biological response modifier in humans and raise the possibility of a novel combination approach to immunomodulation involving cyclooxygenase inhibitors and thymosins.

Human gastric mucosal bleeding induced by low dose aspirin, but not warfarin

OBJECTIVE

To investigate the suitability of treatment with low dose aspirin or warfarin, or both, as possible prophylaxis against cardiovascular disease by determining the effect on gastric mucosal bleeding.

DESIGN

Randomised crossover trial.

SETTING

Academic department of therapeutics.

SUBJECTS

Twenty healthy male volunteers aged 19-22.

INTERVENTIONS

On separate occasions and in randomised order all subjects received aspirin 75 mg, warfarin, or aspirin 75 mg combined with warfarin. Each treatment was given for 12 days or (when warfarin was used) for longer if necessary until the international normalised ratio of the prothrombin time was stable at 1.4-1.6.

END POINT

Loss of blood over 10 minutes into gastric washings.

MEASUREMENTS AND MAIN RESULTS

Bleeding over 10 minutes into gastric washings under baseline conditions and after five days, and at end of each regimen of treatment. Aspirin 75 mg increased bleeding from 0.60 (95% confidence interval 0.36 to 0.99) microliters/10 minutes to 1.26 (0.71 to 2.25) microliters/10 minutes at five days, with no evidence of either progressive change or adaptation thereafter. Warfarin had no effect on bleeding either alone or when combined with aspirin.

CONCLUSIONS

Aspirin 75 mg causes gastric mucosal bleeding. Low dose warfarin neither induces gastric mucosal bleeding nor enhances that caused by aspirin.

Aspirin-induced gastric mucosal injury: lessons learned from animal models

This review of the mechanisms by which aspirin causes gastric mucosal damage points to the involvement of two potential mechanisms. Aspirin, which inhibits cyclooxygenase, is rapidly deacetylated to salicylate. Salicylate is toxic to cells and affects mucosal barrier function, reduces cytosolic adenosine triphosphate, stimulates sodium transport, and increases proton dissipation from surface epithelial cells. Cyclooxygenase inhibition makes the gastric mucosa more susceptible to injury, inhibits mucus and bicarbonate secretion, alters the physicochemical nature of mucus, stimulates fundic but not antral [3H]thymidine incorporation, and reduces epithelial surface hydrophobicity. No single mechanism seems to be involved. It is likely, instead, that the toxic effects of salicylate and the effect of cyclooxygenase inhibition work in concert to render the mucosa more susceptible to injury, resulting in mucosal damage.

In vivo measurement of thromboxane B2 and 6-keto-prostaglandin F1 alpha in humans in response to a standardized vascular injury and the influence of aspirin

The effects of smoking, aspirin ingestion, and sex differences on bleeding times and bleeding time thromboxane B2 and 6-keto-prostaglandin (PG)F1 alpha production were examined. Nonsmoking men produced more thromboxane B2 (3.99 +/- 0.76 ng/ml) than nonsmoking women (2.13 +/- 0.24 ng/ml). Female smokers produced more thromboxane B2 (5.01 +/- 0.97 ng/ml) than nonsmoking women. Twenty-four hours after a single dose of 600 mg aspirin, in vitro production of thromboxane B2 in response to collagen fell by 95%, whereas in vivo production of thromboxane B2 and 6-keto-PGF1 alpha in bleeding time blood fell by 87% and 66%, respectively. Subjects with the lowest absolute levels of thromboxane B2 24 hours after aspirin were also those with the longest postaspirin bleeding times. Recovery of 6-keto-PGF1 alpha production was faster than recovery of thromboxane B2 production, but 6-keto-PGF1 alpha production for most subjects was still below basal 72 hours after aspirin. The influence of two different doses of long-term aspirin (80 mg every other day and 325 mg daily) on the in vivo production of thromboxane B2 and 6-keto-PGF1 alpha was studied in normals and diabetics. After 14 days of 80 mg aspirin every other day, thromboxane B2 and 6-keto-PGF1 alpha production were both substantially inhibited (93% and 78%, respectively). After 14 days of 325 mg aspirin daily, thromboxane B2 production was similarly substantially inhibited (93%), whereas 6-keto-PGF1 alpha was significantly less affected (only 45% inhibition). Study of a second group of five normal subjects confirmed that 6-keto-PGF1 alpha production was significantly inhibited 24 hours after the first dose of 325 mg aspirin but was not significantly less than basal after 14 days of 325 mg aspirin. The results suggest that 325 mg aspirin daily is more antithrombotic compared with 80 mg every other day due to the superior preservation of prostacyclin production.

Aspirin and prevention of myocardial infarction

Determining the cardioprotective effects of aspirin (acetylsalicylic acid) remains a focus for both basic science and clinical investigation. Although other contributors are probably present, the favorable prostacyclin-to-thromboxane ratio induced by low-dose aspirin appears beneficial for reducing cardiovascular mortality associated with unstable angina and myocardial infarction. The precise dosage, frequency and timing of aspirin's administration to reduce the incidence of vaso-occlusive events remains to be determined. This article reviews aspirin's mechanism of action and use for the prevention of myocardial infarction.

Salicylates in the treatment of arthritic disease. How safe and effective?

Despite the adverse effects of aspirin, many physicians still consider it to be the drug of choice for initial treatment of arthritic disorders. Nonsteroidal antiinflammatory drugs (NSAIDs) are better tolerated than aspirin but have similar, although milder, side effects. The nonacetylated salicylates appear to have fewer adverse effects than either aspirin or the NSAIDs and therefore may warrant greater consideration as first-line therapy for arthritis.

Inhibition of platelet function by low-dose plain and micro-encapsulated acetylsalicylic acid

The effect of two acetylsalicylic acid (ASA) formulations, plain (Magnyl) and micro-encapsulated (Globentyl), on platelet aggregation, thromboxane formation, and bleeding time was studied in 12 healthy volunteers in a randomized double-blind cross-over study. All subjects were treated with Magnyl and Globentyl (75 mg daily) in periods of 2 weeks, separated by a wash-out period of 2 weeks. Both drugs significantly depressed platelet aggregation and thromboxane formation and prolonged bleeding time without difference in mode of action of the drugs. It is concluded that significant inhibition of platelet activity may be achieved by low-dose ASA treatment with micro-encapsulated as well as with plain formulations.

Aspirin in cardiovascular disease

Although other mechanisms may be contributory, the antithrombotic properties of aspirin derive predominantly from its platelet-inhibitory effects. These are mediated via irreversible acetylation of platelet cyclo-oxygenase with subsequent blockade of platelet thromboxane synthesis. Long term administration of doses of aspirin as low as 20mg daily depresses platelet thromboxane formation by more than 90%; however, higher doses appear to be necessary to prevent thromboxane-dependent platelet activation in vivo. While there is evidence of biochemical selectivity with low doses of aspirin, significant reduction of the platelet-inhibitory eicosenoid, prostacyclin, occurs even at dosages ranging from 20 to 40mg daily. The ability of aspirin to prevent the occurrence or recurrence of vaso-occlusion has been extensively investigated. In the secondary prevention of myocardial infarction 7 placebo-controlled trials involving more than 15,000 patients have been completed. The dose of aspirin varied from 300 to 1500mg daily. Although none of the individual trials produced statistically significant reductions in total or coronary mortality, taken together the results are highly suggestive of a beneficial effect of aspirin. Similarly, 2 recent studies in patients with unstable angina demonstrated a protective effect of aspirin against acute myocardial infarction and death. While each study employed widely different doses of aspirin (324mg and 1250mg daily) similar reductions in mortality were reported. The effects of aspirin on the prevention of coronary artery bypass graft occlusion have been evaluated in 9 trials. Aspirin in doses of 100 to 975mg daily was shown to be of benefit in preventing early (less than 6 months) graft occlusion, particularly when therapy was started within 24 hours of operation. In patients with prosthetic vascular grafts of the lower limbs, aspirin has been shown to reduce platelet deposition, however further controlled trials will be required to establish the patient population most likely to benefit and, as in all these studies, the optimum dose of aspirin to employ. In patients with prosthetic heart valves it is clear that aspirin alone is insufficient to prevent thromboembolic complications and when administered as an adjunct to anticoagulant therapy it is associated with a high incidence of bleeding. In contrast, there is convincing evidence from several studies for the efficacy of aspirin in doses of 990 to 1300mg daily in the prevention of stroke and death in patients with transient ischaemic attacks.(ABSTRACT TRUNCATED AT 400 WORDS)

Platelets and antiplatelet therapy in ischemic heart disease

Blood platelets have been shown to play an important role not only in thrombosis, but also in the pathogenesis of coronary artery disease and its complications. Drugs that affect platelets have been shown to reduce mortality in survivors of acute myocardial infarction, to reduce the risk of myocardial infarction in patients with unstable angina, and to preserve the potency of saphenous venous grafts used to bypass obstructed coronary arteries. The drugs may also play a role in the primary prevention of arteriosclerosis and in preventing thrombotic complications following coronary angioplasty.

Pharmacokinetics of low-dose oral modified release, soluble and intravenous aspirin in man, and effects on platelet function

The pharmacokinetics of low-dose aspirin and the resulting salicylic acid were studied in 6 healthy volunteers. Each received a single 50-mg dose of (1) oral modified release capsules, (2) oral solution and (3) intravenous solution. The volunteers also received 50 mg modified release capsules daily for 6 days to determine the effect on collagen, ADP and arachidonate induced platelet aggregation and thromboxane production, and to compare the pharmacokinetics after repeated dosing with the parameters obtained after the single dose. The formulation and route of administration profoundly influenced several pharmacokinetic parameters for aspirin: the maximum concentration (Cmax, ng.ml-1) was 221 and 191 after modified release for single and chronic dosing respectively, 1323 after the oral solution and 6000 after intravenous injection; the time to achieve this maximum concentration (tmax, h) was 3.42 and 3.02 after modified release for single and chronic dosing respectively, and 0.29 after the oral solution; the area under the plasma drug concentration versus time curve (AUC, microgram.h.ml-1) was 0.38 and 0.27 after modified release single and chronic dosing respectively, 0.68 after the oral solution and 1.57 after intravenous injection. The elimination of aspirin after the two solutions was at least biphasic. The terminal phase rate constant ranged from 1.52 h-1 after intravenous injection to 1.88 h-1 after the oral modified release form. The absorption of the oral forms of aspirin was complete as reflected by the total recovery of the doses as salicylic acid in urine.(ABSTRACT TRUNCATED AT 250 WORDS)

Low-dose acetylsalicylic acid (ASA) plus dipyridamole versus dipyridamole alone in the prevention of stroke in patients with reversible ischemic attacks

A total of 243 patients who had reversible ischemic attacks (RIA) were submitted to clinical trial to determine whether dipyridamole (400 mg/day) (D) or aspirin (100 mg/48 hours) + dipyridamole (300 mg/day) (ASA + D) would produce significant reduction in the subsequent occurrence of RIA and completed stroke. One hundred and fifteen were selected for Group ASA + D and 71 were treated with dipyridamole only. The treatment groups were similar in relation to age, sex, risk factors, duration and presumed vascular territory of RIA, incidence of alterations of arterial supra-aortic trunks, cerebral infarct (CT scan), and platelet function. Patients were followed for a mean time of 21 months. At the end of the study, 21.7% of the ASA + D group and 19.7% in the D group had suffered new episodes of RIA or completed stroke (p = 0.88). Frequency of stroke (reversible ischemic neurologic deficit or completed stroke) was 7.8% in the ASA + D patients and 9.8% in the D patients (p = 0.83). Subgroup analysis did not show significant differences either. It is concluded that ASA + D has no significantly greater beneficial effect than that observed with D alone in the secondary prevention of atherothrombotic cerebral ischemia. However, a statistical Type II error cannot be excluded by the reduced number of recurrences.

Low dose aspirin treatment in late pregnancy differentially inhibits cyclo-oxygenase in maternal platelets

Eighteen pregnant women were treated with aspirin, 37.5 mg once daily by mouth. Treatment was started two weeks before the expected date of delivery, and continued until delivery. Seventeen untreated women were studied concurrently. Platelet thromboxane (TX) production was determined by radioimmunoassay of TXB2 in serum from blood incubated for one hour with thrombin at 37 degrees C. Maternal blood was studied before treatment and at delivery. Fetal blood, from the cord, was studied at delivery. Prostacyclin (PGI2) production by rings of umbilical artery incubated in Hanks' solution at 37 degrees C for one hour was determined by radio-immunoassay of its hydrolysis product, 6-oxo-prostaglandin (PG) F1 alpha. Maternal and fetal blood from untreated women produced similar amounts of TXB2. Aspirin, in the dose regimen used, significantly inhibited TXB2 production in maternal but not in fetal blood, and did not impair PGI2 synthesis by umbilical artery rings. This differential effect on the cyclo-oxygenase of maternal platelets is probably due to the unusual kinetic properties of aspirin, and may prove therapeutically useful.

Prevention of recurrent idiopathic fetal growth retardation by low-dose aspirin and dipyridamole

In a controlled, nonrandomized trial a treatment group of 24 multigravid women with a history of at least two previous pregnancies, all complicated by idiopathic fetal growth retardation and placental infarction, received 1 to 1.6 mg/kg aspirin and 225 mg dipyridamole daily from 16 to 34 weeks' gestation in a total of 30 pregnancies. The end-point measure of the study was birth weight related to gestational age. Results obtained in the treatment group were compared with those in 27 pregnancies of a control group of 24 multigravid women with a similar history of recurrent fetal growth retardation who received comparable antenatal care without low dose aspirin and dipyridamole. Fetal growth retardation occurred in 61% of the control pregnancies and in only 13% of treated pregnancies; severe fetal growth retardation was not observed in treated pregnancies, but it occurred in 27% of the control group. In treated women, platelet cyclo-oxygenase activity was suppressed to 5% to 10% of its pretreatment level, but no effect on vascular prostacyclin production was demonstrated. Treatment did not produce adverse effects in mothers or infants. Low-dose aspirin and dipyridamole direct prostacyclin/thromboxane A2 balance in pregnancy to the dominance of prostacyclin and may thus prevent idiopathic uteroplacental insufficiency and fetal growth retardation in high-risk patients.

Effect of 50 mg enteric-coated aspirin (Astrix) on thromboxane and prostacyclin synthesis

Although low-dose soluble aspirin can be recommended as a useful anti-thrombotic drug regimen in patients with vascular disease, enteric-coated preparations have a theoretical advantage for aspirin preparations which are to be ingested daily for many years. We have demonstrated that a 50 mg enteric-coated aspirin formulation (Astrix) which has an absorption rate much lower than soluble aspirin, is sufficient to inhibit platelet thromboxane synthesis while causing no major decrease in vascular prostacyclin synthesis.

Platelet aggregation and platelet-inhibiting drugs

Platelet function may cause a progression of central gray matter damage after cerebrospinal hemorrhage or trauma because of the thrombotic occlusion of injured vessels or a vasospasm induced by extravasated blood. It has therefore been suggested that antiplatelet drugs could limit the extent of the neurological lesions produced by a spinal trauma. In view of this possibility, the hemostatic functions of platelets and the mechanism of action of antiplatelet drugs are briefly reviewed.

Aspirin prolongs bleeding time in uremia by a mechanism distinct from platelet cyclooxygenase inhibition

We reported that aspirin (ASA) abnormally prolongs bleeding time (BT) in uremia. The present study was designed to investigate whether the abnormally prolonged post-ASA BT in uremia is due to different ASA pharmacokinetics and bioavailability that might be a consequence of uremic condition, platelet cyclooxygenase is peculiarly sensitive to ASA in uremia, and ASA affects primary hemostasis in uremia by a mechanism independent of cyclooxygenase inhibition. Our results showed that in patients with uremia, but not in normal subjects, ASA markedly prolongs the BT. This effect is transient and depends on the presence of ASA in the blood. The observed differences in ASA kinetic parameters are not an explanation of the exaggerated effect of ASA on primary hemostasis in uremia. The sensitivity of platelet cyclooxygenase to ASA inhibition is comparable in uremics and in normal subjects. The temporal dissociation between ASA-induced prolongation of BT and the effect on platelet thromboxane A2 generation suggests that ASA inhibits platelet function in uremia by a mechanism distinct from cyclooxygenase blocking. This possibility is strengthened by the observation that ibuprofen at a dose that fully inhibits platelet cyclooxygenase activity does not significantly prolong BT.

Stimulation of prostacyclin production in blood vessels by the antithrombotic drug suloctidil

Suloctidil is a calcium antagonist with vascular relaxing activity and an antithrombotic agent: its antiplatelet action has been demonstrated in vivo, but is difficult to reproduce in vitro and the mechanism of this effect remains unknown. We have observed that suloctidil (10 microM) stimulated the release of prostacyclin (PGI2) from the rabbit aorta, the dog vena cava and the dog portal vein, in vitro. This effect could be explained by an increased mobilization of free arachidonic acid. Neither the inactive congener CP894S, nor the two calcium channel antagonists, verapamil and flunarizine, reproduced the stimulatory effect of suloctidil. Suloctidil acted selectively on the vascular endothelium: it stimulated the release of PGI2 from bovine aortic and human umbilical vein endothelial cells, but neither from the de-endothelialized rabbit aorta nor from the bovine aortic media. The stimulatory effect of suloctidil on the release of the platelet inhibitor PGI2 from the vascular endothelium might contribute to the known antiplatelet and antithrombotic activity of this drug.

A dose-ranging study of the antiplatelet effect of enteric coated aspirin in man

Enteric coated aspirin was given to eight human volunteers in escalating doses (20, 40, 60, 80, 100 mg daily), each dose being given over two weeks. In addition, to measure the maximum effect of aspirin, each volunteer was given two single doses of 600 mg of soluble aspirin. At the end of each dosing interval we measured platelet aggregation and thromboxane formation in response to four aggregating agents and to whole blood coagulation. The doses of aspirin required to inhibit platelet aggregation in response to various stimuli were: for collagen 60-80 mg, for adenosine diphosphate and adrenaline 60 mg, and for arachidonate 40 mg. For maximum inhibition of thromboxane formation the doses were: for collagen greater than 100 mg, for adenosine diphosphate and adrenaline 60 mg, for arachidonate 80 mg, and for whole blood coagulation 100 mg. Different aspirin doses are required to inhibit the responses to different stimuli. Furthermore, for some stimuli, inhibition of thromboxane generation may require more aspirin than is required for inhibition of aggregation. The clinical implications of these findings are uncertain since we do not know which stimuli are important in arterial thrombosis in man.

The extracellular control of intracellular aspirin hydrolysis

We have previously presented evidence that an intra-erythrocyte arylesterase is primarily responsible for the deacetylation of aspirin to salicylate. We now report studies on extracellular control factors. The fractional acetylsalicylic acid (ASA) hydrolysis at the completion of 20-minute incubations in suspensions of washed red blood cells (RBC) with human serum albumin (HSA) decreased sharply, from 0.6 at 0 gm/dl HSA to 0.2 at 5.0 gm/dl HSA. In RBC suspensions with oleic, linoleic, and lauric acid, ASA hydrolysis increased as fatty acid:HSA ratios increased. The addition of salicylate (SA) also resulted in an increase in the fraction hydrolyzed. In a separate, more direct, ultracentrifugation assay, unbound ASA levels were similarly affected by HSA and the other ligands. When SA and oleic acid were incubated with ASA in RBC, additive competition for binding sites was apparent at relatively low levels of the fatty acid. In the presence of increasing concentrations of sodium SA, 5-amino SA, and 4-amino SA, ASA hydrolysis in RBC suspensions was increased by an average of 137%, 75%, and 54%, respectively. The most reasonable explanation for these findings is that the intact ASA molecule binds to albumin and that the binding of competing ligands can modulate the levels of free ASA in the circulation. This, in turn, affects the amount of drug available as substrate for penetration into the RBC and reaction with the intracellular hydrolase which catalyzes ASA deacetylation. Such factors controlling drug availability, if validated in vivo, could be important with regard to the antiinflammatory and anti-platelet properties of aspirin.

Eicosanoid biosynthesis in human cardiovascular disease

Thromboxane A2, the predominant cyclooxygenase product in platelets, is a potent platelet agonist and vasoconstrictor in vitro. Prostacyclin, the major product of vascular endothelium, has opposite effects on platelet function and vascular tone. These properties prompted the hypothesis that a "balance" between these compounds regulated interactions between platelets and the vessel wall in vivo. Although this possibility has been addressed extensively through experiments in vitro, clinical investigations commonly have been confounded by problems with analytic methodology, by selection of inappropriate metabolic targets for analysis, and by artifacts of trial design. The most reliable forms of assessing biosynthesis that are currently available still do not provide definitive information as to the tissue of origin of the compound studied and are directed toward stable but biologically inactive metabolites rather than the evanescent primary compounds themselves. Despite these limitations, both biochemical evidence and clinical trials clearly implicate thromboxane A2 as an important mediator of vascular occlusive disease in humans. The role of prostacyclin is much more conjectural. It does not circulate in concentrations sufficient to exert a systemic effect, but it may play a local homeostatic role in the regulation of platelet-vascular interactions. Whether preservation of the capacity to form prostacyclin coincident with inhibition of thromboxane A2 is of functional importance can be addressed only by clinical trials comparing inhibitors of thromboxane synthesis inhibition that are selective with cyclooxygenase inhibitors that also block the biosynthesis of prostacyclin. The recognition that multiple factors have the potential to regulate both platelet and vascular function at their interface renders the concept of a thromboxane A2-prostacyclin "balance" somewhat unlikely. However, both eicosanoids may interact with other factors to determine the development or persistence of vascular occlusion. Inhibition of the synthesis or function of thromboxane A2 remains the predominant mechanism for achieving interference with platelet function in vivo. Accumulating evidence for the efficacy of aspirin in human syndromes of vascular occlusion suggests that the biologic role of these compounds in humans should be pursued.

Aspirin and other antiplatelet drugs in the prophylaxis of thrombosis

Aspirin is of proven value as an antithrombotic drug. In unstable angina it reduces the risk of death and myocardial infarction by half. After a myocardial infarction it reduces the risk of death by about 10% and of coronary incidence (coronary death or definite myocardial infarction) by about 25%. These effects appear to be additive with those of beta-blocking drugs. Aspirin also reduces the risk of occlusion of aortocoronary saphenous vein grafts by about half. In transient cerebral ischaemia, aspirin may reduce the risk of stroke and death by 50%. In most clinical trials to date the daily dose of aspirin ranges from 325 mg to 1400 mg. Interest in very low doses of aspirin (less than 60 mg daily) is considerable but has yet to be translated into proven clinical benefit. Dipyridamole has not been shown to be effective as an antithrombotic when used alone. Its antiplatelet action ex vivo may be enhanced by combination with aspirin but clinical trials have shown relatively little advantage of the combination over aspirin alone. Sulphinpyrazone has not become established as a first line antithrombotic drug. Epoprostenol is useful in extracorporeal circulations to prevent platelet consumption and possibly in severe inoperable peripheral vascular disease.

Pharmacokinetics of aspirin and salicylate in relation to inhibition of arachidonate cyclooxygenase and antiinflammatory activity

Among the nonsteroid antiinflammatory drugs there is generally a close correlation between the potency of their inhibition of arachidonate cyclooxygenase, and thus prostaglandin production, and their antiinflammatory activity. One anomaly in this generalization is that whereas aspirin and salicylate are equipotent as antiinflammatory agents, salicylate is less active than aspirin in inhibiting prostaglandin production in vitro. Using rats, we have now measured the concentrations of aspirin and salicylate in plasma and in inflammatory exudates after their oral administration and determined their effects on thromboxane B2 production in clotting blood and prostaglandin (PG) E2 concentrations in the exudates. We have also investigated the effects of both drugs, at concentrations achieved in the exudates, on PGE2 production by nonproliferative explants of acutely inflamed tissues. Aspirin is rapidly metabolized, resulting in peak concentrations of salicylate in the plasma and exudate that exceeded peak concentrations of aspirin by 30- to 50-fold. Furthermore, concentrations of aspirin rapidly declined, whereas high concentrations of salicylate persisted in the plasma and in the exudate for up to 6 hr after a single administration of aspirin. Both drugs reduced PGE2 concentrations in inflammatory exudates by 50-70%, but aspirin was considerably more potent than salicylate in inhibiting thromboxane B2 production in clotting blood. The concentration of salicylate found in inflammatory exudates 6 hr after the administration of aspirin was sufficient to reduce PGE2 production in explants by more than 50%. We conclude that the antiinflammatory action of both drugs depends on the inhibition of PGE2 synthesis by salicylate.

Effects of low doses of aspirin, 10 mg and 30 mg daily, on bleeding time, thromboxane production and 6-keto-PGF1 alpha excretion in healthy subjects

To compare the long term effects of two low doses of aspirin taken daily, we performed a placebo-controlled cross-over study in 19 normal subjects. Aspirin 10 mg daily for 3 weeks caused a significant inhibition by 61 +/- 12 percent of platelet thromboxane B2 generation but had no effect on the Simplate bleeding time. Aspirin 30 mg daily for 3 weeks reduced thromboxane B2 production by 94 +/- 5 percent and caused a significant prolongation of the bleeding time, 1.6 times the control value. No cumulative inhibitory effects were observed after the first week of treatment. Both doses did not effect the urinary excretion of 6-keto-PGF1 alpha.