Comparison of the in vivo hemorrhagic and antithrombotic effects of a low antithrombin-iii affinity heparin fraction

Antithrombin III (ATIII) affinity chromatography of commercial grade heparin yields fractions of high and low affinity for ATIII. In vitro, the high affinity fraction accounts for most of the anticoagulant effect while there is evidence that the low affinity material interferes with platelet function. We have studied the relative antithrombotic and hemorrhagic effects of low affinity heparin. The low affinity heparin fraction, specific activity 43 USP units/mg, was compared with standard heparin (150 USP units/mg) in rabbit experimental models. A residual 12.5% by weight of this low affinity heparin showed high affinity for ATIII. Inhibition of thrombosis in a stasis-hypercoagulability model was directly related to the weight (mg) of high affinity material in each of the heparins. In the bleeding model, when similar weights (mg) of high affinity material were infused, significantly more bleeding was demonstrated with the low affinity fraction which contained a 5-fold excess by weight of low affinity material. We have demonstrated that a low affinity heparin depleted of in vitro anticoagulant and in vivo antithrombotic activity significantly contributes to hemorrhage.     

Discordance between the anti-Xa activity and the antithrombotic activity of an ultra-low molecular weight heparin fraction

The relationship between the in vivo antithrombotic effect of heparin and ex vivo anti-Xa activity has been investigated using an animal thrombosis model. Three low molecular weight heparins were compared with the standard heparin from which they were fractionated. All four heparins showed a dose-dependent antithrombotic effect enabling the relative antithrombotic and anti-Xa activities to be compared over a dosage range. A correlation between ex vivo anti-Xa heparin levels and antithrombotic effect was demonstrated for the standard (MW 16,000), intermediate (MW 7,600) and low (MW 4,600) molecular weight heparins but not for the ultra-low molecular weight (MW 3,000) fraction. The lack of relationship between anti-Xa activity and inhibition of thrombosis for the very low molecular weight fraction indicates that a very high anti-Xa activity (measured in vitro or ex vivo) is not always predictive of in vivo antithrombotic efficacy. These findings suggest that other properties of low molecular weight heparins contribute to their antithrombotic effectiveness.     

In vitro and in vivo studies of the anti-Xa activity of heparin

Several heparin preparations have been assayed using the Denson and Bonnar anti-Xa assay. The heat defibrination step involved in this assay has been shown to introduce discrepancies into the results, due mainly to co-precipitation of the heparin with fibrinogen. The amount of heparin lost is dependant on the molecular weight. The anti-Xa activity of ex vivo samples from subjects given heparin was much more resistant to loss during defibrination than in vitro samples, resulting in artificially high potency estimates. A modified assay has been proposed, omitting the defibrination step. The results provide further evidence that the anti-Xa activity observed after subcutaneous injection of heparin differs from that measured when the drug is added to plasma in vitro.     

Studies on a highly active anticoagulant fraction of high molecular weight isolated from porcine sodium heparin

We have studied heparin fractionation using gel filtration and ion-exchange chromatographic methods. The starting material was commercial grade porcine mucosal sodium heparin (PSH). The fractionation was monitored employing synthetic substrates for assaying both antithrombin (with H-D-Phe-Pip-Arg-pNA ; S-2238) and anti-FXa (with Bz-Ileu-Glu-Gly-Arg-pNA ; S-2222) activities. The resulting fractions were evaluated in different amidolytic and coagulation methods used to determine heparin potency by comparison with PSH. By gel filtration of PSH on Ultrogel AcA 54, both strong anti-FXa and antithrombin activities were associated with the fractions eluted in the high molecular weight range (MW 20 × 10³). These fractions also had potent anticoagulant action when assayed by conventional clotting methods. PSH was also subjected to fractionation by an ion-exchange technique (DEAE-Sephacel) with increasing salt molarity. The patterns for antithrombin and anti-FXa activities were again closely related, if not identical. Four fractions were usually distinguished, with respectively negligible, intermediate, high and very high activities when compared to PSH. The very highly active fraction (HAF), approximately 15% by weight, was eluted at high salt molarity (> 0.8 M NaCl). On a weight basis its anticoagulant activity was 2–3 times that of PSH as determined by amidolytic as well as clotting methods. Intravenous injection of HAF to rabbits and dogs (1.0 and 2.5 mg/kg) produced a much stronger anticoagulant response than PSH, also showing an effect which persisted for a longer duration.     

Anticoagulant and antithrombotic effects of heparin and low molecular weight heparin fragments in rabbits

Heparin and heparin fragments of different molecular weight and with different anti-factor X_a/APTT activity ratios were studied with respect to their ability to inhibit thrombus formation in an animal model. It is concluded that: a) Neither anti-factor X_a nor the APTT activity alone is a good reflector of the antithrombotic activity. b) Anti-factor X_a active fragments must have a minimum molecular weight in order to elicit good antithrombotic activity. c) High affinity for antithrombin III is important for good antithrombotic activity. d) A heparin fragment of molecular weight 4 000 has the same antithrombotic activity as heparin but less effect on the clotting time.     

Pharmacokinetics of a low molecular weight heparin, Logiparin, after intravenous and subcutaneous administration to healthy volunteers

In six healthy volunteers we have estimated the pharmacokinetic parameters of the anti factor Xa (AXa) and anti factor IIa (AIIa) activities of a LMW heparin, Logiparin. For the AXa the following parameters were estimated in a 1-compartment model (mean and 95% confidence limits in brackets): elimination half life 82 minutes (60–127 min), absorption half life (s.c.inj.) 200 minutes (137–368 min), bioavailability 90% (24–156 %), and apparent volume of distribution 3.9 1 (3.1–5.2 1). The plasma activity was linearly correlated to the dose given and to the body weight of the volunteer. For the AIIa the parameters estimated in a 1-compartment model were: elimination half life 71 minutes (52–115 min), absorption half life 257 minutes (133–3442 min), bioavailability 67% (44–90 %), and apparent volume of distribution 10.1 1 (7.2–16.7 1). The plasma activity was dependent on dose and body weight but it also seemed to be influenced by individual factors. This study shows that the absorption rate is the rate limiting factor and the explanation for the long lasting effect of this LMW heparin after subcutaneous injection. The slow absorption rate and the high bioavailability are probably the major advantages of LMW heparins compared to conventional heparin.     

Effect of heparin on in vitro platelet reactivity in cardiac surgical patients-a comparative assessment by whole blood platelet aggregometry and haemostatometry

The effect of heparin on platelet reactivity was assessed simultaneously by haemostatometry (response to shear stress) and whole blood platelet aggregometry response to collagen (WBPA). From each blood sample a ratio (H_R for haemostatometry and M_R and I for WBPA) showing platelet reactivity in the presence or absence of heparin (5 U/ml) was calculated. A value < 1 represented a proaggregatory effect and > 1 an inhibitory effect. Non-anticoagulated blood samples obtained from 290 cardiac surgical patients were tested by haemostatometry and citrated whole blood samples from 100 patients with aggregometry.

Haemostatometry demonstrated a proaggregatory effect of heparin in 8.6% (25) and an inhibitory effect in 91.4% (265). Assessed by WBPA, heparin was proaggregatory in 41–46% and inhibitory in 54–59%.

In the 100 patients tested by both methods there was a significant correlation between the findings with the two techniques (r = 0.46, p < 0.0001).

A wide individual variation in the platelet effect of heparin was demonstrated. This variation appeared greater and a higher proportion showed inhibition when blood was tested by haemostatometry.     

Lack of correlation between "in vitro" and "in vivo" antithrombotic activity of heparin fractions and related compounds. Heparan sulfate as an antithrombotic agent "in vivo"

The anticoagulant (U.S.P., APTT; "in vitro" and "in vivo") antithrombotic (aXa; Yin and Wessler and chromogenic), antilipemic (LPL) activities of heparin, heparin fractions and fragments, heparinoids, heparan sulfate and other sulfated glycosaminoglycans were compared with the activities of these compounds as antithrombotics "in vivo" by four different methods (vena cavae ligature, kaolin, collagen and steel coil). A lack of correlation was observed between the activities "in vitro" and the antithrombotic activity "in vivo". For instance heparan sulfate which shows negligible pharmacological activities "in vitro" is a potent antithrombotic agent "in vivo". Likewise, several heparin fractions and fragments have low aXa activity "in vitro" and high antithrombotic activity "in vivo". It is concluded from these results that the "in vitro" tests used cannot predict the antithrombotic activity "in vivo".     

Subcutaneous administration of heparin a randomised comparison with intravenous administration of heparin to patients with deep-vein thrombosis

One-hundred and forty-one patients with clinical signs of acute deep venous thrombosis (DVT) in the legs were randomly allocated to recieve heparin either as two daily subcutaneous injections (s.c.) or as continuous intravenous infusion (i.v.). The thrombi extended into the popliteal or femoral veins in 83% of the patients. Verification of diagnosis and evaluation of therapy was performed by phlebography, plethysmography and thermography.

The results showed that heparin administered s.c. twice daily was as efficient as continuous i.v. infusion in preventing extension of the thrombus. In two patients the s.c. administration was stopped due to local haematomas at the injection sites. Retroperitoneal or intramuscular bleedings occurred in four patients, two in each group. Two major, non-fatal pulmonary emboli occurred, one in each group.     

Inhibition of the cerebroside sulphate (sulphatide)-induced contact activation reactions by platelet factor four

Cerebroside sulphate or sulphatides, present in erythrocyte and leucocyte cell membranes, have recently been shown to be a potent activator of the contact phase of coagulation. Platelet factor-four (PF4), purified from human washed platelets, was found to inhibit the sulphatide induced APTT and plasma prekallikrein activation in a dose dependent manner. A four-fold increase in the sulphatide-APTT was observed at 156pM PF4 in the reaction mixture and 30% inhibition of prekallikrein activation was observed at 1.6nM. PF4 was found to be an approximately 1000-fold more potent inhibitor than protamine sulphate in inhibiting activation of clotting but was not as potent in inhibiting activation of prekallikrein. The physiological form of PF4 as released from platelets, was also found to cause inhibition of plasma prekallikrein activation, with 50% inhibition observed when the concentration of PF4 in plasma was 2.25 g/ml (0.29 M). The ability of PF4 to inhibit the contact activation reactions induced by sulphatides may be of some physiological significance in that when released during platelet activation and vessel wall injury, it may have a protective effect against the development of thrombosis.     

Anticoagulant and lipolytic effects of a low molecular weight heparin fraction

The lipolytic and anticoagulant actions of a 4000 dalton low molecular weight (LMW) heparin were compared with unfractionated mucosal heparin after intravenous and various subcutaneous doses in man. I.v. injection of 100 USP units/kg body weight lipoprotein lipase (LPL) activity, and inhibition of factor Xa decreased with a half life twice as long after LMW heparin compared to normal heparin (p < 0.05). There were no differences in half lives for HTGL activity, thrombin inhibition and on aPTT. The area under the activity time curve (AUC) of LPL and factor Xa was double with LMW heparin (p < 0.05). S.c. administration showed that the AUC of LMW heparin on the factor Xa inhibition was 10 times larger compared to normal heparin. LPL activity was released comparable to normal heparin. The effects on HTGL were three times larger compared to normal heparin. There were no differences in half lives. The data show that in contrast to normal heparin LMW heparin is rapidly and completely absorbed from the subcutaneous depots. The pharmacodynamic data of LPL activity and factor Xa inhibition suggest similar release mechanisms.     

Laboratory monitoring of thromboprophylaxis with low molecular weight and standard heparin

This study was made to evaluate assays for monitoring of low dose heparin thromboprophylaxis and to evaluate its efficacy in reduction of hypercoagulation. Patients with medical diseases scheduled for routine thromboprophylaxis were subcutaneously treated with either 5.000 anti XaU low molecular weight (LMW) heparin once daily (n=20) or 5.000 IU standard (ST) heparin 3 times daily (n= 19). On days 1,2,3, before, 1 and 4 hours after heparin injection APTT, TCT, anti Xa, Heptest, thrombin-antithrombin complexes (TAT), and D-Dimer levels were measured. In the LMW heparin group, median values of APTT and TCT slightly increased after heparin and the ranges of pre- and postinjection values showed extensive overlap. However, values of anti Xa and Heptest markedly increased, showing complete separation of ranges. In the ST heparin group neither APTT, TCT, anti Xa, nor Heptest were significantly different comparing pre- and postheparin values. Half of the patients in both groups had subclinical hypercoagulation at baseline (TAT>5ng/ml, D-Dimer>200ng/ml). On day 3 of prophylaxis this percentage was not significantly decreased. Moreover, several patients in both groups increased in TAT and D-Dimer. In the LMWheparin group, negative correlations between body weight and 4 h postinjection heparin levels were found (anti Xa R=−0.50, Heptest R=−0.31) and between 1 h postinjection heparin and TAT and D-Dimer levels 3 h later (TAT-anti Xa R=−0.58, TAT-Heptest R=−0.64, D-Dimer-anti Xa R=−0.32, D-Dimer-Heptest R=−0.33). These results show that low dose LMW but not ST heparin therapy can be monitored by the anti Xa test or the Heptest.     

Importance of a 3-0-sulfate group in a heparin pentasaccharide for antithrombotic activity

Previous theoretical and experimental evidence led to the formulation of a specific pentasaccharide structure which represents the site in heparin for binding to antithrombin III. This pentasaccharide was subsequently synthesized. A pentasaccharide of the same structure but lacking only the sulfate group on the hydroxyl group of the middle glucosamine (position C-3) was also synthesized to test the structure - activity relationships. Previous biochemical studies showed the 3-0-desulfated pentasaccharide to have a low affinity binding to AT III and to be devoid of the high anti-factor Xa activity characteristic of the pentasaccharide. Our in vivo studies, in a venous stasis thrombosis model proved the 3-0-desulfated pentasaccharide, at equigravimetric dosages, to be devoid of the antithrombotic activity previously reported for the pentasaccharide. These studies confirm the fact that inhibition of factor Xa at a high level of activity produces an antithrombotic effect.     

The in vivo release of human platelet factor 4 by heparin

Intravenous and subcutaneous injection of heparin or the heparin analogue SSHA into normal volunteers induced release of platelet factor 4 (PF4) but not beta-thromboglobulin (beta-TG). At low heparin doses the amount of PF4 released was related to the plasma heparin concentration achieved. The rise in plasma PF4 was coincident with, and appeared to be a response to, the increase in plasma heparin concentration rather than to the absolute heparin level. After the primary response, the system became refractory to further challenge by the same heparin dose; the full initial magnitude of the response was not regained until 144 h. after heparin was first injected. The maximum amount of PF4 released corresponded to only about 5% of that potentially available from platelets. Moreover, heparin did not stimulate PF4 release from whole blood in vitro. We have demonstrated the presence of PF4 on the vascular endothelium, and suggest that this is the immediate source of the PF4 released by heparin, though it is probably initially derived from platelets. The effect of such binding on the antithrombotic potential of the endothelial surface is discussed.     

Demonstration of a direct anti-factor Xa activity in certain heparin-related glycosaminoglycans

Heparan sulphate/heparin subfractions with high plasma anti-Xa activity have an unusual uronate composition, i.e. high proportions of both glucuronate and sulphated iduronate. These preparations inhibit the amidase activity of factor Xa in an uncompetitive mode and the prothrombin-activation catalyzed by Xa, both in the absence of antithrombin III. Subfractions of low affinity for antithrombin III are equally potent against Xa. The anti-X activity is destroyed by a 3-h periodate oxidation.