A regimen for low-dose aspirin?

The effects of different regimens of 40 mg aspirin on platelet thromboxane A2 synthesis and vascular prostacyclin synthesis were determined in patients who were undergoing elective surgery for removal of varicose veins. Aspirin 40 mg taken at intervals of 48 hours consistently reduced platelet thromboxane A2 synthesis to a level at which it failed to support platelet aggregation and the associated release reaction. This effect lasted for at least 36 hours. In contrast, aspirin 40 mg every 72 hours did not have the same consistent effect. Both dose regimens led to a reduction in vascular prostacyclin synthesis 12 hours after the last dose, but 36 or 72 hours after the last dose prostacyclin synthesis was not reduced; thus the inhibition of prostacyclin synthesis was short lived. If the balance between platelet thromboxane A2 and vascular prostacyclin synthesis is important in thrombosis 40 mg aspirin every 48 hours may have the maximum antithrombotic effect.     

Dose-related effects of low dose aspirin on hemostasis parameters and prostacyclin/thromboxane ratios in late pregnancy

Background: The purpose of this study was to determine which low dose of low dose aspirin (LDA) optimized the urinary prostacyclin (PGI₂)/thromboxane (TXA₂) ratio and minimized evidence of platelet aggregation during normal late pregnancy.Methods: Twelve women with uncomplicated singleton pregnancies between 28 and 34 weeks gestation participated in a randomized blinded study. Blood samples for salicylate levels were obtained pretreatment, 4 hours and 7 days after administration of placebo, 20mg, 40mg or 80mg of aspirin. Twenty-four hour urine specimens collected at the same intervals were assayed for PGI₂ and TXA₂ metabolites. In addition, bleeding time and platelet aggregation studies were performed prior to and after 7 days of LDA or placebo.Results: A dose-related increase in bleeding time occurred with 40 mg and 80 mg of LDA, but not with the 20 mg dose or placebo. Platelet aggregation studies changed progressively from a normal baseline to abnormal with an increasing dose of LDA. The ratio increased with aspirin doses as low as 20mg, with a decrease in TXA₂ metabolites but not in PGI₂ metabolites. Serum salicylate was not detectable in any sample from any patient.Conclusion: There are dose-related changes in platelet aggregation and bleeding times with progressively increasing doses of LDA. A lower dose of LDA, such as 20–40 mg per day, may be as efficacious as higher doses in the prophylaxis of pre-eclampsia in high risk populations.     

Non-steroidal anti-inflammatory drugs react with two sites on platelet cyclo-oxygenase evidence from ‘in vivo’ drug interaction studies in rats

Non-steroidal anti-inflammatory drugs inhibit platelet cylco-oxygenase activity. This study shows that salicylate, diflunisal, sulphinpyrazone and indomethacine prevent in vivo aspirin inhibitory effect of cyclo-oxygenase activity as measured by the formation of malondialdehyde and thromboxane B₂, two products of platelet arachidonic acid metabolism. Salicylate also prevents the inhibitory effect of indomethacin. All these drugs therefore appear to interact with the same site on platelet cyclo-oxygenase. Since salicylate is inactive by itself on this platelet enzyme and diflunisal and sulphinpyrazone were used at ineffective doses, it is suggested that their interaction with aspirin (or indomethacin) occurs at the level of a supplementary site is necessary but not sufficient for the efficacy of these drugs as cyclo-oxygenase inhibitors. Acetylation by aspirin of the active site appears to be a phenomenon secondary to the binding of salicylate moiety to the supplementary site.     

Eicosanoids in preeclampsia

Preeclampsia is characterized by an imbalance between two cyclooxygenase metabolites of arachidonic acid, thromboxane and prostacyclin, that favors thromboxane. Because of the biologic actions of these two eicosanoids, this imbalance might explain major clinical symptoms of preeclampsia, such as hypertension, platelet aggregation and reduced uteroplacental blood flow. In the maternal circulation, this imbalance is primarily manifested by decreased production of prostacyclin by endothelial cells. Platelet thromboxane synthesis is only increased in severe preeclampsia. In the placenta and in leukocytes, the imbalance is exacerbated by increased production of thromboxane coupled with decreased production of prostacyclin in both mild and severe preeclampsia. Longitudinal measurements of urinary metabolites of thromboxane and prostacyclin reveal that the thromboxane/prostacyclin imbalance predates the onset of clinical symptoms of preeclampsia. The imbalance between thromboxane and prostacyclin is most likely caused by oxidative stress, which is manifest in preeclampsia by increased lipid peroxidation and decreased antioxidant protection. Oxidative stress may drive this imbalance because lipid peroxides activate the cyclooxygenase enzyme to increase thromboxane synthesis, but at the same time they inhibit prostacyclin synthase to decrease prostacyclin synthesis. Low-dose aspirin therapy (50-150 mg/day) has been considered for the prevention of preeclampsia because it selectively inhibits thromboxane synthesis. Several studies reported dramatic decreases in the incidence of preeclampsia with low-dose aspirin therapy. However, two large multicenter studies reported only modest decreases, which dampened enthusiasm. The two large studies were "intent to treat" studies which included patients who were noncompliant and who discontinued the use of aspirin. In one of the studies for which compliance statistics were available only 53% of the aspirin group had a compliance rate greater than 75%, which raises a question as to whether the effectiveness of aspirin was being tested. Low-dose aspirin therapy should not yet be dismissed for the prevention of preeclampsia, but be reconsidered with emphasis on compliance using doses of aspirin in the range of 100-150 mg/day combined with antioxidants.     

Slow intravenous administration of low dose aspirin inhibits both vascular and platelet cyclooxygenase activity: an experimental study in the rat

Aspirin irreversibly inhibits cyclooxygenase, thus preventing thromboxane (Tx)A2 production in platelets and prostacyclin in vascular cells. While it is generally accepted that the inhibitory effect of low dose aspirin is cumulative on platelet cyclooxygenase, it is still a matter of debate whether a similar phenomenon also occurs on vascular cyclooxygenase. We have measured in anesthetized rats the inhibitory effect of two doses of aspirin (2.5 and 5.0 mg/kg), given intravenously either as a bolus or as a continuous infusion (for 30 min), on platelet TxB2 and 6-ketoprostaglandin F1 alpha generation by different vascular segments. Aspirin significantly inhibited both platelet and vascular cyclooxygenase independently of the rate of drug administration. The aspirin peak plasma levels at the end of bolus injection was about 170 times higher than the average level measured during the slow infusion (1.21 +/- 0.15 micrograms/ml). At this concentration aspirin did not affect in vitro either platelet or vascular cyclooxygenase activity. Thus the inhibitory effect of aspirin on both platelet and vascular cyclooxygenase seems to be related to total exposure of the enzyme to the drug rather than to the maximal drug concentration attainable in the systemic circulation. These findings may be relevant to the current debate on optimal conditions for the biochemical selectivity of aspirin as an antithrombotic drug.     

The role of prostacyclin in vascular tissue.

Prostacyclin (PGI2) generated by the vascular wall is a potent vasodilator, and the most potent endogenous inhibitor of platelet aggregation so far discovered. Prostacyclin inhibits platelet aggregation by increasing cyclic AMP levels. Prostacyclin is a circulating hormone continually released by the lungs into the arterial circulation. Circulating platelets are, therefore, subjected constantly to prostacyclin stimulation and it is via this mechanism that platelet aggregability in vivo is controlled. Moreover, phosphodiesterase inhibitors such as dipyridamole or theophylline exert their antithrombotic actions by potentiating circulating prostacyclin. The prostacyclin:thromboxane A2 ratio is important in the control of thrombus formation; manipulation of this ratio by small doses of aspirin (which will inhibit mainly platelet cyclooxygenase), a selective inhibitor of thromboxane formation, or the dietary use of a fatty acid like eicosapentaenoic acid (which would be the precursor for a delta17-prostacyclin (PGI3) but is transformed by the platelets into nonaggregating thromboxane A3) might have beneficial effects as antithrombotic therapies. Prostacyclin has interesting potential for clinical application in conditions where enhanced platelet aggregation is involved or to increase biocompatibility of extracorporeal circulation systems.     

The effects of an infusion of prostacyclin on their endotoxin shock in rabbits.

30 rabbits received an infusion of lipopolysaccharide B (75 micrograms/kg.h) over 4 hours (groups E, EI, EA; n = 10 each). Saline was given to a control group (C; n = 8). In group EI, prostacyclin (PGI2; 500 ng/kg.min) was given simultaneously to endotoxin. Into group EA animals, aspirin (20 mg/kg) was injected before the endotoxin infusion was started. PGI2 and aspirin both improved survival of animals (6/10 each vs. 2/10 in group E). The drop of platelet counts was significantly reduced by PGI2, while leukocyte depletion was similar in all endotoxin groups. PGI2 preserved the functional capacity of platelets as indicated by collagen stimulated aggregation and thromboxane formation. PGI2 but not aspirin significantly reduced renal fibrin deposition.     

Comparison of pharmacokinetic and pharmacodynamic profiles of aspirin following oral gavage and diet dosing in rats

Aspirin is one of the oldest drugs and has been purported to have multiple beneficial effects, including prevention of cardiovascular disease and cancer, in addition to its original indication for treatment of inflammation, fever and pain. In cancer chemoprevention studies using animal models, two methods of aspirin administration have been employed: oral gavage and diet. The untested assumption was that exposure and the resultant pharmacological effects are similar for these two administration methods when dosing is normalized on the basis of mg/kg body weight/day. This study examined and compared time-dependent plasma and colon mucosal concentrations of aspirin metabolite salicylate (aspirin concentrations were below level of quantification), plasma thromboxane B(2) concentrations, and colon mucosal prostaglandin E(2) concentration following these two different dosing paradigms in rats. Diet dosing yielded relatively constant plasma and colon salicylate concentration vs. time profiles. On the other hand, oral gavage dosing led to a rapid peak followed by a fast decline in salicylate concentration in both plasma and colon. Nevertheless, the exposure as measured by the area under plasma or colon concentration-time curve of salicylate was linearly related to dose irrespective of the dosing method. Linear relationships were also observed between colon and plasma salicylate areas under the curve and between colon prostaglandin E(2) and plasma thromboxane B(2) areas under the curve. Therefore, more easily accessible plasma salicylate and thromboxane B(2) concentrations were representative of the salicylate exposure and prostaglandin E(2) pharmacodynamic biomarker in the target colon, respectively.     

Action of nonsteroidal anti-inflammatory agents on fibrinolysis and platelet aggregation

The influence of non-steroidal antiphlogistics (NSA, fluor derivatives of phenylanthranilic acid) on fibrinolysis, platelet function, prostaglandin metabolism and pharmacokinetics of indirect anticoagulants was studied in rats and rabbits in vitro and in vivo. NSA were found to shorten the euglobulin lysis time and to enlarge the lysis zones on fibrin plates. They potentiated the fibrinolytic activity of streptokinase and trypsin. Furthermore, they inhibited platelet aggregation induced by arachidonic acid in rabbits. NSA in combination with inhibitors of thromboxane synthetase potentiated inhibition of aggregation. After oral administration, NSA inhibited formation of thromboxane A2 and prostacyclin in rabbits in a dose-dependent manner. At comparatively low doses, thromboxane A2 synthesis was more effectively inhibited than prostacyclin formation. Due to pharmacokinetic interactions NSA enhanced the anticoagulant effect of indirect anticoagulants and accelerated their distribution and elimination.     

De-aggregatory action of prostacyclin in vivo and its enhancement by theophylline.

In the mixed venous blood of anaesthetized, heparinized cats prostacyclin de-aggregated platelet thrombi, which were formed on the surface of blood-superfused collagen strips or on the surface of blood-superfused aortic strips from atherosclerotic rabbits. The reversal of platelet aggregation by prostacyclin was still achieved 3 hrs after the formation of platelet clumps. After an intravenous injection of prostacyclin the ID50 for its de-aggregatory action was 7.5 microgram/kg. Theophylline ethyl-diamine (aminophylline), at a dose of 3 mg/kg i.v., did not reverse platelet aggregation but it enhanced the duration of the de-aggregatory action of prostacyclin; it had little effect on the hypotensive action of prostacyclin. It is concluded that prostacyclin disintegrates platelet clumps long after they are formed in heparinized blood in vivo and that its anti-platelet action, but not hypotensive action, is selectively potentiated by a phosphodiesterase inhibitor. The above experimental data indicate the possibility of the combined use of theophylline and prostacyclin in arterial thrombosis.     

Role of lipoxygenase metabolism in platelet function: Effect of aspirin and salicylate

Aspirin inhibits thromboxane A₂ (TxA₂) production whereas its salicylate moiety inhibits 12-hydroxy-eiosatetraenoic acid (12-HETE) production in the platelet. The significance of the latter effect on platelet function is unclear. We examined the effects of aspirin and salicylate on (i) platelet/ collagen adhesion using ³H-adenine-labelled human platelets and collagen- coated discs, (ii) platelet aggregation induced by thrombin, collagen, ADP and arachidonic acid, and (iii) platelet TxA₂ and 12-HETE synthesis as measured by radioimmunoassay and high pressure liquid chromatography respectively. Aspirin (50 μM) decreased platelet aggregation and increased platelet adhesion. The decrease in aggregation was associated with inhibition of TxA₂ production and the increase in adhesion was associated with enhanced 12-HETE production. Salicylate had the opposite effects. Platelet aggregation was increased and platelet adhesion decreased. The increased aggregation was associated with enhanced TxA₂ production and the decrease in aggregation was associated with inhibition of 12-HETE production. These observations suggest that 12-HETE facilitates platelet adhesion which can be altered by salicylate treatment.     

De-aggregatory action of prostacyclin and its enhancement by theophylline

In the mixed venous blood of anaesthetized, heparinized cats prostacyclin de-aggregated platelet thrombi, which were formed on the surface of blood-superfused collagen strips or on the surface of blood-superfused aortic strips from atherosclerotic rabbits. The reversal of platelet aggregation by prostacyclin was still achieved 3 hrs after the formation of platelet clumps. After an intravenous injection of prostacyclin the ID₅₀ for its de-aggregatory action was 7.5 μg/kg. Theophylline ethyldiamine (aminophylline), at a dose of 3 mg/kg i.v., did not reverse platelet aggregation but it enhanced the duration of the de-aggregatory action of prostacyclin; it had little effect on the hypotensive action of prostacyclin. It is concluded that prostacyclin disintegrates platelet clumps long after they are formed in heparinized blood and that its anti-platelet action, but not hypotensive action, is selectively potentiated by a phosphodiesterase inhibitor. The above experimental data indicate the possibility of the combined use of theophylline and prostacyclin in arterial thrombosis.     

De-aggregatory action of prostacyclin in vivo and its enhancement by theophylline

In the mixed venous blood of anaesthetized, heparinized cats prostacyclin de-aggregated platelet thrombi, which were formed on the surface of blood-superfused collagen strips or on the surface of blood-superfused aortic strips from atherosclerotic rabbits. The reversal of platelet aggregation by prostacyclin was still achieved 3 hrs after the formation of platelet clumps. After an intravenous injection of prostacyclin the ID₅₀ for its de-aggregatory action was 7.5 μg/kg. Theophylline ethyldiamine (aminophylline), at a dose of 3 mg/kg i.v., did not reverse platelet aggregation but it enhanced the duration of the de-aggregatory action of prostacyclin; it had little effect on the hypotensive action of prostacyclin. It is concluded that prostacyclin disintegrates platelet clumps long after they are formed in heparinized blood $\text{in vivo}$ and that its anti-platelet action, but not hypotensive action, is selectively potentiated by a phosphodiesterase inhibitor. The above experimental data indicate the possibility of the combined use of theophylline and prostacyclin in arterial thrombosis.     

Aspirin inhibits rat megakaryocyte thromboxane synthesis

This study examines the question of whether the aspirin-induced delay in the recovery of platelet cyclooxygenase pathway activity, as measured by RIA of thromboxane B₂, results from a direct effect on megakaryocyte cyclooxygenase. From our measurement of recovery of TXB₂ and information on megakaryocyte transit time in rats, we propose that thromboxane synthesis may represent a relatively late step in the differentiation of megakaryocytes. Megakaryocyte thromboxane production was depressed by 70% and that of platelets by 85% at two hr after 20 mg/kg oral aspirin dissolved in DMSO. Full megakaryocyte thromboxane recovery occurred by 72 hr and preceded complete platelet thromboxane recovery by 24 hr. Whereas megakaryocyte thromboxane synthesis showed substantial recovery by 36 hr after aspirin, platelet recovery did not begin for 24 hr and achieved a maximal recovery rate over the following 12 hr. This finding is consistent with predictions based upon human data for both megakaryocyte labeling studies and post-aspirin platelet recovery. We conclude from our data and from estimates of megakaryocyte maturation times in marrow, that thromboxane synthesis develops in rat megakaryocytes after approximately 48 hr of cytoplasmic differentiation toward platelet shedding. This metabolic capacity therefore serves as a marker of megakaryocyte differentiation.     

Plasma lipoproteins affect platelet malondialdehyde and thromboxane B2 production

Platelet interaction with plasma lipoproteins was studied using gel-filtered platelets free of plasma constituents and purified lipoproteins. On incubation of gel-filtered platelets with plasma lipoproteins at 30 degrees C for 30 min, 100 micrograms of protein/ml of very-low as well as low-density lipoprotein caused 10% increment in platelet aggregation and [14C]serotonin release in parallel to elevation of around 15% of malondialdehyde and thromboxane B2 production. High-density lipoprotein showed the opposite effect and reduced platelet aggregation as well as thromboxane B2 synthesis by 17 and 32%, respectively. Lipoprotein-deficient plasma enhanced platelet function. Preincubation of the platelet suspension with prostacyclin did not prevent the effect of the lipoproteins on the in vitro platelet response as well as on the platelet prostaglandin pathway. Our results suggest that the formation of thromboxane B2 and malondialdehyde is influenced by plasma lipoproteins and that these, in turn, affect platelet aggregation and the release reaction. The possible significance of these results to platelet function in hyperlipidemic patients is discussed.     

Effect of low-dose aspirin in combination with stable fish oil on whole blood production of eicosanoids

The effect of a combination of aspirin and fish oil on eicosanoids was studied. Four subjects were given 37.5 mg aspirin orally, and 6 weeks later they received a natural, stable fish oil daily for 1 week before taking the same single dose of aspirin. Blood samples for determination of whole blood production of eicosanoids were taken before and after each experimental period. Serum thromboxane A(2)was decreased by 40% (P<0.05) after aspirin alone, but by 62% (P<0.01) after fish oil + aspirin. Serum prostacyclin (measured as 6-keto PGF(1a)) was decreased by aspirin in both cases. The sum of 6-keto PGF(1a)and its equipotent fish oil-derived analogue Delta(17)-6-keto PGF(1a)was reduced after aspirin intake (55%, NS), but after fish oil + aspirin the reduction was smaller (33%, NS). Leukotriene B(4)was increased by 19% (P<0.05) after aspirin, and decreased by 69% (P<0.05) after fish oil + aspirin. A combination of stable fish oil and aspirin thus improves the eicosanoid pattern more than aspirin alone.     

The effect of aspirin and two nitric oxide donors on the infarcted heart in situ

Nitric oxide (NO) donors are heterogeneous substances which release NO, a biologically active compound. NO released by nitric oxide donors has important effects on the circulation by causing vasodilation, diminishing myocardial contractile force, inhibiting platelet aggregation, and counteracting the effects of thromboxane A2. In the infarcted heart, activation of the inducible form of nitric oxide synthase (iNOS) and the formation of prostacyclin and thromboxane A2 by cyclooxygenase (COX) were increased. Myocardial infarction also resulted in increased myocardial NO production. Aspirin (acetylsalicylic acid. ASA) at low concentration (35 mg/kg/day) fails to change iNOS production, in contrast to higher dose (150 mg/kg/day) which, as previously shown, inhibits iNOS activity. ASA at all doses also suppresses myocardial prostanoid formation because of inhibition of COX. Recently, two NO donors have been synthesized: NCX 4016 and Diethylenetriamine/NO (DETA/NO). NCX 4016 combines an NO-releasing moiety with a carboxylic residue via an esteric bond. We describe here that NCX 4016 (65 mg/kg/day) increased prostacyclin and thromboxane A2 production in the infarcted heart muscle, overcoming the inhibitory effects of ASA. As a result of nitric oxide release, oxidation products of NO (NO2- and NO3-; NOx) in arterial blood rose following administration of NCX 4016. On oral administration, NCX 4016 did not change systemic arterial pressure. The effects of a single NO donor, DETA/NO (1.0 mg/kg/day) on the infarcted heart were also investigated On intravenous administration, the compound increased NO concentration in arterial blood slightly but to a lesser degree than NCX 4016. Like NCX 4016, it raised myocardial production of prostacyclin and thromboxane A2 in the infarcted heart. However, it caused a severe fall in blood pressure. These findings demonstrate that newly-synthesized NO donors release nitric oxide in situ and increase myocardial production of prostanoids. NCX 4016 has therapeutic potential because it can be orally administered, lacks hypotensive effects, increases blood levels of nitric oxide and myocardial prostacyclin production.     

Equivalent inhibition of in vivo platelet function by low dose and high dose aspirin treatment

In vitro platelet function was inhibited in healthy volunteers by two different doses of aspirin, as confirmed by measurement of maximum serum production of thromboxane B2 (TXB2) by platelets. 75 mg aspirin did not fully inhibit serum TXB2 production after 24 hours, whereas 300 mg aspirin did. Inhibition of platelet function in vitro was maintained by both 75 mg/day aspirin or 300 mg/alternate day aspirin. In contrast, in vivo production of TXB2, measured as urinary levels of the 11-keto-TXB2 metabolite, was inhibited similarly by both doses of aspirin throughout the study. These findings suggest that 75 mg/day aspirin may be sufficient adequately to inhibit platelet aggregation in vivo.     

Measurements of 6-keto-prostaglandin F1 alpha and thromboxane B2 in bleeding time blood: relation to bleeding and vascular disorders?

The body's ability to produce prostacyclin and thromboxane by blood vessels and platelets may be important in hemostatic and thrombotic disorders and in blood pressure regulation. There are limitations to the information that can be derived from measurement of the active substances or metabolites in plasma and urine. Assays for thromboxane and prostacyclin in bleeding time blood reflect production in response to a single standardized vascular injury, and show considerable promise in furthering our understanding of the production of these chemicals in vivo. These assays may improve the assessment of risk of developing thrombotic disorders and improve the ability to monitor treatment. Studies to date have focused largely on the influences of various doses of aspirin on the production of prostacyclin and thromboxane in bleeding time blood, but also suggest that smokers are high thromboxane producers. In addition, individuals who exhibit type A behavior, a behavior pattern characterized by a relatively high level of ambitiousness, hostility, and competitive drive and a chronic sense of urgency appear to be low prostacyclin producers. Diets enriched in sunflower oil were found to diminish thromboxane production, while diets high in canola oil enhanced prostacyclin formation.     

Pronounced reduction of in vivo prostacyclin synthesis in humans by acetaminophen (paracetamol)

The effect of a single dose of 500 mg acetaminophen (paracetamol) on the in vivo synthesis of prostacyclin was studied in healthy volunteers by measurements of the urinary excretion of 2,3-dinor-6-keto-PGF1 alpha. Acetaminophen caused a marked reduction of prostacyclin synthesis for 6-8 hours without any obvious effect on the thromboxane synthesis. Thus, acetaminophen may at least theoretically be disadvantageous for patients suffering from diseases where prostacyclin mediated vascular defence mechanisms are activated, like myocardial infarction, deep vein thrombosis and following surgery.