Janice Rischke

Aspirin inhibits platelet function independent of the acetylation of ciclo-oxygenase

Aspirin inhibits platelet function and prevents thrombosis in some clinical situations. This antithrombotic effect is attributed to the irreversible inhibition of platelet thromboxane A2 synthesis, an effect which is achieved by a low dose of aspirin. There is some evidence that higher doses of aspirin may have additional antithrombotic effects. To test this possibility, we measured the effect of high and low dose aspirin on hemostasis in vivo and platelet function ex vivo in the rabbit. Both carotid arteries were isolated. One was replaced with a 2 cm piece of polyethylene tubing and the other was left intact. The prosthetic and intact vessels were then punctured with a needle and the time take for bleeding from each to cease was measured. Aspirin (3 and 100 mg/kg given 1 or 20 hours before hand) had no effect on the bleeding from the intact vessel, but prolonged the bleeding time in the prosthetic vessel in a dose-related manner. Washed platelets obtained from the 100 mg/kg-treated rabbits were less responsive to collagen and thrombin than platelets obtained from the 3 mg/kg-treated rabbits which in turn, were less responsive than control platelets. This additional effect of aspirin on platelet function was not due to the further inhibition of platelet thromboxane A2 release nor to further inhibition of the platelet release phenomenon. It is suggested that the enhanced effect of high dose aspirin on haemostasis from the arterial prosthesis is related to the second platelet inhibiting effect of aspirin.

In vitro comparison of the effect of heparin, enoxaparin and fondaparinux on tests of coagulation.

Low-molecular weight heparin (LMWH) is increasingly used in place of unfractionated heparin (UFH) in patients with unstable angina, and phase II clinical trials using fondaparinux for this indication are underway. Because unstable angina patients often require urgent percutaneous coronary interventions (PCI) or aortocoronary bypass surgery, a point-of-care test is needed to monitor the anticoagulant effect of these agents. The activated clotting time (ACT) and activated partial thromboplastin time (aPTT) are the tests most often used to monitor heparin. The purpose of this in vitro study was to determine whether the ACT or the aPTT can be used to monitor the anticoagulant effect of low-molecular weight heparin and fondaparinux. The ACT and aPTT were measured after heparin, enoxaparin or fondaparinux was added to the blood of healthy volunteers, in doses with equivalent inhibitory activity against activated factor X (factor Xa). To mimic the clinical scenario where an unstable angina patient, who has already received enoxaparin, is urgently taken for PCI or bypass surgery, the ACT was determined after heparin was added to blood containing clinically relevant doses of enoxaparin. We determined that enoxaparin produced significantly less prolongation of both the ACT and the aPTT than heparin, whereas fondaparinux had no effect on either of these tests. Addition of enoxaparin to heparin-containing plasma did not prolong the ACT beyond that produced by heparin alone. The ACT and aPTT therefore cannot be used to monitor low-molecular weight heparin or fondaparinux, highlighting the need for a point-of-care anti-factor Xa assay.

Effect of nonspecific binding to plasma proteins on the antithrombin activities of unfractionated heparin, low-molecular-weight heparin, and dermatan sulfate

BACKGROUND Nonspecific binding to plasma proteins decreases the anti-factor Xa (anti-Xa) activity of unfractionated heparin (UFH) but not that of low-molecular-weight heparin (LMWH). However, plasma proteins could influence the anti-thrombin (anti-IIa) activity of LMWH. To explore this possibility, we compared the effects of plasma proteins on the anti-IIa activities of UFH and LMWH. We also examined their effects on the anti-IIa activity of dermatan sulfate (DS) because, like UFH, DS binds to plasma proteins. METHODS AND RESULTS There was almost complete recovery of anti-IIa activity when UFH, LMWH, or DS was added to plasma from each of 20 healthy volunteers. The addition of a chemically modified heparin with low affinity for antithrombin III to plasma containing UFH increased the anti-IIa activity in a concentration-dependent fashion by displacing UFH from plasma proteins. In contrast, addition of low-affinity heparin had no effect on the anti-IIa activity of LMWH. LMWH does not bind to plasma proteins because the bulk of the LMWH chains are < 6000 D, and only heparin fractions > 6000 D bind nonspecifically to plasma proteins. As further evidence that plasma proteins do not influence the anti-IIa activity of LMWH, the rate of thrombin inhibition in plasma in the presence of LMWH is virtually identical to that in buffer containing physiological amounts of the major antithrombins. In contrast, with UFH or DS, the rate of thrombin inhibition is twofold slower in plasma than in buffer. CONCLUSIONS Nonspecific binding of UFH to plasma proteins most likely contributes to the variable anti-IIa response to UFH in patients with thromboembolic disease. Although DS also binds to plasma proteins, the clinical significance of this finding is unclear. In contrast, because LMWH does not bind to plasma proteins, the anti-IIa activity of LMWH should be just as predictable as its anti-Xa activity.

The sex-related differences in aspirin pharmacokinetics in rabbits and man and its relationship to antiplatelet effects

There are a number of reports which suggest that the antithrombotic effect of aspirin is limited to males. It is unclear whether this effect is due to sex-related differences in the effect of aspirin on platelets, the vessel wall, or the pharmacokinetics of aspirin. To test these possibilities we examined the sex-related differences in (1) vessel wall PGI2 release and its inhibition by and recovery from aspirin in rabbits; (2) the effects of aspirin on platelet aggregation, thromboxane B2 and beta-thromboglobulin (BTG) release in man, and (3) the pharmacokinetic characteristics of aspirin, in both rabbits and man. Vascular wall PGI2 measured as 6-keto-PGF1 alpha, was not different in male and females rabbits, and was inhibited to a similar extent by identical concentrations of aspirin. The duration of this inhibitory effect was also the same in males and females. The pattern of inhibition of collagen-induced platelet aggregation, and collagen-induced thromboxane B2 and BTG release by aspirin were not different in either sex. There was, however, a sex-related difference in a number of pharmacokinetic characteristics of aspirin both in rabbits and man. Thus, aspirin was absorbed more rapidly, distributed in larger apparent volume and was hydrolysed more rapidly in females. These observations suggest that the sex-related differences in the antithrombotic effects of aspirin seen in clinical studies are not due to differences in the effects of aspirin on the inhibition of platelet function mediated by the inhibition of cyclo-oxygenase in either the platelet or the vessel wall. An effect of aspirin on platelet function independent of the inhibition of cyclo-oxygenase has been described and it is possible that this effect may be influenced by sex-related differences in the pharmacokinetics of aspirin.

Thrombin-activable fibrinolysis inhibitor attenuates (DD)E-mediated stimulation of plasminogen activation by reducing the affinity of (DD)E for tissue plasminogen activator. A potential mechanism for enhancing the fibrin specificity of tissue plasminogen activator.

A complex of d-dimer noncovalently associated with fragment E ((DD)E), a degradation product of cross-linked fibrin that binds tissue plasminogen activator (t-PA) and plasminogen (Pg) with affinities similar to those of fibrin, compromises the fibrin specificity of t-PA by stimulating systemic Pg activation. In this study, we examined the effect of thrombin-activable fibrinolysis inhibitor (TAFI), a latent carboxypeptidase B (CPB)-like enzyme, on the stimulatory activity of (DD)E. Incubation of (DD)E with activated TAFI (TAFIa) or CPB (a) produces a 96% reduction in the capacity of (DD)E to stimulate t-PA-mediated activation of Glu- or Lys-Pg by reducing k cat and increasingK m for the reaction; (b) induces the release of 8 mol of lysine/mol of (DD)E, although most of the stimulatory activity is lost after release of only 4 mol of lysine/mol (DD)E; and (c) reduces the affinity of (DD)E for Glu-Pg, Lys-Pg, and t-PA by 2-, 4-, and 160-fold, respectively. Because TAFIa- or CPB-exposed (DD)E produces little stimulation of Glu-Pg activation by t-PA, (DD)E is not degraded into fragment E and d-dimer, the latter of which has been reported to impair fibrin polymerization. These data suggest a novel role for TAFIa. By attenuating systemic Pg activation by (DD)E, TAFIa renders t-PA more fibrin-specific.

The pharmacokinetics of flurbiprofen in younger and elderly patients with rheumatoid arthritis.

The pharmacokinetics of flurbiprofen (Ansaid Tablets, Upjohn Company of Canada, Don Mills, Ontario) were evaluated in both younger (40 to 60 years) and elderly (65 to 83 years) rheumatoid arthritic patients after both a 100‐mg single‐dose administration and at steady state during a 100‐mg twice‐a‐day dosage regimen. Both flurbiprofen plasma concentration‐time profiles and the urinary excretion of flurbiprofen and its major metabolites were evaluated. The results indicate that the pharmacokinetics of flurbiprofen are linear in both age groups based on only minor changes between single‐dose and steady‐state parameter determinations and the agreement between calculated and predicted accumulation values in plasma concentrations. Only minor differences in the pharmacokinetic parameters were observed between the younger and elderly patients. Only free flurbiprofen clearance was found to have a significant but variable correlation to patient age. The effect of flurbiprofen on the urinary excretion of two prostaglandins were also evaluated throughout this study. In both age groups, the maximum decrease in urinary excretion was observed after the first dose, and this effect was maintained throughout the remainder of the study. Percent decreases from baseline in urinary excretion during drug administration were similar for both age groups. Similar side‐effect profiles were observed between age groups.

Effects of misoprostol on the pharmacokinetics of indomethacin in human volunteers.

The effects of misoprostol (200 μg as a single dose or q.i.d. as a multiple dose) on the pharmacokinetics of indomethacin (100 mg single‐dose administration or 50 mg t.i.d. multiple‐dose administration) were studied in 16 healthy human volunteers under single‐dose and steady‐state conditions in a randomized, double‐blind, placebo‐controlled, balanced three‐period study design. The overall absorption as shown by the values for area under the concentration curve of indomethacin was unaffected by concurrent administration of misoprostol. However, misoprostol did significantly enhance the steady‐state maximum concentration of indomethacin by 32%. Thus misoprostol does not interfere with the absorption of indomethacin despite the known inhibitory effects of this protaglandin analog on acid secretion.

Antithrombin activity of gold sodium thiomalate

Gold sodium thiomalate has been shown to inhibit serine esterase enzymes isolated from the lysosomes of white cells. We demonstrate for the first time to our knowledge that gold sodium thiomalate is inhibitory to the serine esterase thrombin in its interaction with washed human platelets, human platelet‐rich plasma, and human platelet‐poor plasma. Since thrombin is a serine esterase phylogenetically related to the serine esterases elastase and cathepsin G, the most likely mechanism of action is an interaction of the gold thiol complex with one or all of the four cysteine–cysteine disulfide bridges of the thrombin molecule.