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3 Pharmacokinetics of heparin and low molecular weight heparin

After parenteral injection, heparin is removed from the blood via two mechanisms, saturable and non-saturable. The saturable mechanism represents clearance by the reticuloendothelial system and endothelial cells, to which heparin binds with a high affinity. The non-saturable mechanism is represented by renal excretion. The contribution of the two mechanisms to the clearance of heparin varies according to the dose delivered and the molecular weight of the heparin preparation. At low doses, unfractionated heparin (UH) is removed mainly via the saturable mechanism, while at higher doses the contribution of the non-saturable mechanism to its clearance becomes pre-eminent. This model accounts for the major pharmacokinetic properties of UH. After bolus intravenous injection of low doses, UH disappears from the blood exponentially with a dose-dependent half-life; at higher doses, UH disappears with a concave-convex pattern. Under continuous intravenous infusion there is a non-linear relationship between the dose of UH injected and the steady-state plasma concentration. After subcutaneous injection, the bioavailability of the anti-factor Xa activity increases with the dose delivered and tends toward 100% at high doses. In contrast, low molecular weight heparins (LMWH) are mainly removed by non-saturable renal excretion. This explains the dose independence of the pharmacokinetic parameters of LMWH, the excellent bioavailability of the subcutaneous route at any dose, and the prolongation of LMWH half-life in cases of chronic renal insufficiency. However, the model does not explain the large interindividual variability of the pharmacokinetic parameters of both UH and LMWH.

Respective role of antithrombin III and heparin cofactor II in the in vitro anticoagulant effect of heparin and of various sulphated polysaccharides

Summary. The in vitro anticoagulant effects of standard heparin (SH) and of seven other sulphated polysaccharides (SPS) were investigated by measuring activated partial thromboplastin time (APTT) prolongation of normal plasma and of plasmas selectively depleted of antithrombin III (AT III), of heparin cofactor II (HCII) and of both heparin cofactors. This allowed the determination of the relative contribution of each of the two heparin cofactors to the SPS anticoagulant effect. The SPS varied in their relative activities as catalysts of thrombin inhibition by purified AT III or HC II. The anticoagulant activities of heparin and dermatan sulphate were primarily attributable to their ability to enhance thrombin inhibition by AT III and HC II respectively. Heparin had an additional minor anticoagulant activity which was independent of both AT III and HC II. Pentosan polysulphate, high molecular weight dextran sulphate, heparin with low affinity for AT III and a sulphated heparin derivative had weaker anticoagulant activities in normal plasma than standard heparin. The anticoagulant activities of these last four SPS in plasma depleted of both AT III and HC II were similar to their respective activities in normal plasma. This suggests that these SPS act by directly preventing thrombin generation rather than by enhancing thrombin inhibition.

Effects of lysophosphatidic acid on proliferation and cytosolic Ca++ of human adult vascular smooth muscle cells in culture.

Lysophosphatidic acid (LPA) is a lipid mediator generated by activated platelets and having various effects on numerous cell types. We investigated some effects of 1-oleyl LPA on vascular smooth muscle cells cultured from adult human normal arteries. At micromolar concentrations, LPA induced a mitogenic effect ([3H]-thymidine incorporation and cell proliferation) on quiescent cells, without an additional growth factor being required. This effect was equipotent to that of 10% fetal calf serum, and it was accompanied by early (5 minutes) and late (1-3 hours) phosphorylation of mitogenactivated protein kinase. LPA inhibited cell migration through collagen coated membranes, with or without platelet-derived growth factor BB as chemoattractant. LPA induced a typical biphasic Ca2+ signal response made up of a rapid first phase due to Ca2+ release from intracellular stores followed by a second wave due to external Ca2+ influx. These findings support the proposal that LPA released from activated platelets is a mediator for smooth muscle cell response at the site of vessel injury in humans.

Evidence for a saturable mechanism of disappearance of standard heparin in rabbits

This work demonstrates that after bolus intravenous injection standard heparin (SH) disappearance results from the combination of a saturable and a non saturable mechanism. Pharmacokinetics and pharmacodynamics of SH were studied by measuring the disappearance of increasing doses (5 - 500 anti-factor Xa U/kg) of 125I-heparin and of its biological effects. CPM curves allowed to determine the half lives of heparin according to the dose injected. The half lives were clearly dose dependent and reached a plateau over 100 anti-factor Xa U/kg. The complex curve which describes the amount of heparin cleared per time unit after any given dose has been resolved into its two components reflecting a saturable and a non saturable mechanism of disappearance. For the doses less than 100 anti-factor Xa U/kg the saturable mechanism was preeminent and the anti-factor Xa activity disappearance followed an exponential pattern; for the doses less than 100 anti-factor Xa U/kg the contribution of the non saturable mechanism becomes more important and the anti-factor Xa activity disappearance followed a concave-convex pattern. Further experiments showed that the heparin half life shortened as the circulating anti-factor Xa activity decreased; this phenomenon may explain the concave-convex pattern of the curve of the anticoagulant effect observed after injection of large doses of SH.

Studies on the structural requirements of heparin for the catalysis of thrombin inhibition by heparin cofactor II

The structural requirements of heparin for the catalysis of thrombin inhibition by heparin cofactor II (HC II) were investigated. A series of well characterized heparin derivatives were prepared and their activities were measured using human thrombin in the presence of an excess of purified human HC II and, for comparison, antithrombin III (AT III). The 50% inhibitory concentrations of each derivative were calculated and compared with those of unmodified heparin. Heparin activity was strongly dependent on molecular weight (Mr) in a manner grossly comparable for the two inhibitors. High-Mr fractions were the most active. Below 10 kDa, the activity dropped rapidly. A minimum size of 26 residues appeared to be required for HC II activation (against 16-18 for AT III). Below 5 kDa, a residual activity two orders of magnitude lower than that of high-Mr species remained with HC II (but not with AT III). Heparin was selectively desulfated or oversulfated in the O- and/or N-position. When an N-acetyl group was substituted for the original N-sulfate in the glucosamine and the derivative was oversulfated in the O-position, a strong activity with HC activities with both inhibitors decreased when the overall sulfate content (i.e., the charge density) was reduced, and vice-versa. Carboxyl-reduced heparin was also inactive but activity could be restored after O-sulfation. Our results thus suggest that, unlike the case of AT III, no functional group in heparin is critical for optimal thrombin inhibition by HC II. Sulfate and carboxylate are important in as much as they contribute to the global charge of the molecule.

Antithrombotic potencies of heparins in relation to their antifactor Xa and antithrombin activities: an experimental study in two models of thrombosis in the rabbit

Summary. Our purpose was to determine the relative contribution of the antifactor Xa and antithrombin activities of heparin to its antithrombotic potency. The antithrombotic activities of unfractionated heparin (UH), two low molecular weight heparins (LMWH, CY 216 and CY 222) with increasing anti‐factor Xa/antithrombin ratio and a synthetic pentasaccharide (PS) with high affinity to antithrombin III and no antithrombin activity were evaluated. In the Wessler‐thromboplastin model, the most potent antithrombotic agent, on a weight basis, was UH followed by CY 216. CY 222 and the PS which was 40 times less potent than UH. On an antithrombin unit basis, the antithrombotic potencies of UH, CY 216 and of CY 222 were equivalent. Thus, in this model, the antithrombotic effect results from the catalytic action of UH or LMWH on thrombin inhibition. In the Wessler‐serum model, on a weight basis, the antithrombotic effectiveness of UH was unchanged, those of CY 216 and CY 222 were doubled, and that of the PS was increased 10 times. On an anti‐factor Xa unit basis, CY 216 was as effective as UH, and PS as effective as CY 222. On an antithrombin unit basis, CY 216 and CY 222 were equivalent and more potent than UH. Thus, in this model, the antifactor Xa activity of heparin becomes important for its antithrombotic property.

The disappearance of a low molecular weight heparin fraction (CY 216) differs from standard heparin in rabbits.

In previous studies, we have reported that standard heparin (SH) was cleared by two mechanisms, a saturable mechanism which predominated at low doses (less than 100 anti-factor Xa U/kg) and a non-saturable mechanism which predominated at higher doses, when the first mechanism became saturated. In this study, we examined the importance of these two mechanisms in the disappearance of a low molecular weight heparin fraction (LMWH) (CY 216), by comparing the pharmacokinetics and the pharmacodynamics of a wide range of doses of SH and CY 216 (1.5 to 500 anti-factor Xa U/kg). Pharmacokinetics was measured as the disappearance of 125I-radiolabelled SH or CY 216. Pharmacodynamics was measured as the disappearance of the anti-factor Xa activity of SH and CY 216. We found that the saturable mechanism contributed little to the disappearance of CY 216 and that it was cleared predominantly by the non-saturable mechanism at all doses tested. Thus, at low doses (less than 100 anti-factor Xa U/kg), SH was cleared more rapidly than CY 216, whereas at higher doses, CY 216 was cleared more rapidly than SH. We conclude that the mechanism of disappearance of LMWHs differ significantly from those of SH, and that this difference may explain the apparent prolonged anticoagulant activity of LMWHs within the therapeutic range doses.

Reassessment of von Willebrand factor (VWF), VWF propeptide, factor VIII:C and plasminogen activator inhibitors 1 and 2 during normal pregnancy

Summary. The use of von Willebrand factor [VWF antigen (WF:Ag)] measurement as a marker of endothelial cell activation for monitoring hypertensive pregnancies is limited by the poor definition of reference values. We reassessed these reference values using different assays, and those of the propeptide (VWF:Ag II) and factor VIII coagulant activity (factor VIII:C), in a large population of normal pregnancies, at 3‐week intervals of gestational age. Plasminogen activator inhibitors (PAI‐1 and PAI‐2) were measured in parallel. Blood was collected at single time points between 12 weeks and delivery in 306 women undergoing normal singleton pregnancy. For clinical purposes, the VWF:Ag reference values were assay independent and the influence of ABO blood group on VWF:Ag or factor VIII:c was found to be limited during the third trimester. VWF:Ag II was not influenced by the ABO blood group. The ratio, VWF:Ag/factor VIII:C was close to 1·0 throughout pregnancy. In contrast, VWF:Ag II increased more slowly than VWF:Ag and the ratio of VWF:Ag II to VWF:Ag in plasma decreased from 1·00 to 0·5 at term. PAI‐1 and PAI‐2 increased with gestational age, but PAI‐2 decreased during the last 2 weeks, indicating physiological placental regression at the very end of pregnancy.

Effects of increased sulfation of dermatan sulfate on its in vitro and in vivo pharmacological properties

The in vitro and in vivo pharmacological properties of two oversulfated dermatan sulfate (DS) derivatives, S-DS1 and S-DS2, containing 2 and 3.7 sulfate groups/disaccharide unit respectively were compared to those of the parent DS (1 sulfate group/disaccharide unit). In a purified system the ability of S-DS1 and of S-DS2 to catalyse thrombin inhibition by heparin cofactor II was increased by ten- and seventeen-fold respectively. These compounds also had more potent anticoagulant activities in the activated partial thromboplastin time and the thrombin clotting time assays. Plasma immunodepleted in antithrombin III, heparin cofactor II and both cofactors allowed it to be demonstrated that these enhanced anti-coagulant activities were partly (S-DS1) or totally (S-SD2) independent of any plasma cofactors. In spite of these enhanced anticoagulant activities in vitro the oversulfated derivatives did not exhibit an increased antithrombotic activity in a thromboplastin Wessler type model. Moreover, at the doses investigated, S-DS2 had no antithrombotic effect. The influence of oversulfation on the pharmacokinetic pattern of DS was also investigated. As reported for unfractionated heparin, the biological activities generated after IV injection of high doses of S-DS1 and S-DS2 disappeared according to a concave-convex pattern. This may result from the higher affinities of S-DS1 and of S-DS2 toward endothelial cells in comparison with that of DS.

Malondialdehyde (MDA) re-appearance in human platelet density subpopulations after a single intake of aspirin

Abstract The kinetics of malondialdehyde (MDA) re-appearance in human platelet density subpopulations after a single intake of aspirin was studied in three human volunteers. Platelet subpopulations were isolated after an isopycnic centrifugation of platelet rich plasma (PRP) on a discontinuous isoosmotic density gradient of arabino - galactan (stractan). Preliminary experiments show that PRP was representative of the whole blood platelet population, that there was no clear correlation between the mean platelet volume and platelet density, and that the MDA synthesis induced by sodium arachidonate (500 μM) was similar whatever the platelet density. After a single oral intake of 0.50 g of aspirin, the time for full recovery of the initial MDA level in the total platelet population was between 9 1/2 and 11 1/2 days for the three volunteers ; MDA re-appearance is faster in light platelets than in the dense ones which are released with a short delay of 2 1/2 to 3 1/2 days. The interpretation of this finding gives rise to three main hypotheses : (1) dense platelets have a longer time of maturation than light platelets ; (2) young released platelets are heterogenous and their density increases slightly during the first day of their survival ; (3) comparison of the present data with those reported by Corash et al. (Blood 52 , 726, 1978) suggests that light platelets could present a shorter turn-over than dense platelets and that the turn-over of the total platelet population corresponds to the mean.