A comparison of the antithrombotic and haemorrhagic effects of a low molecular weight heparin (LHN-1) and conventional heparin

The antithrombotic effects after intravenous administration of a low molecular weight heparin (LHN-1) and conventional heparin were compared in a rabbit model of experimental thrombosis, where thrombus formation was induced by a combination of endothelial damage and stasis. Both compounds were able to prevent thrombosis completely. However, LHN-1 was significantly less potent than conventional heparin, the ratio between doses with the same antithrombotic effect being 2.4:1 on a weight basis. Bleeding times after administration of LHN-1 and conventional heparin were determined by tail transsection in anaesthetized rats and by template bleeding in the ear of conscious pigs. Given intravenously at a dose ratio of 2.4:1 (w/w), LHN-1 affected APTT less than conventional heparin, whereas the effects on haemostasis were not significantly different. In conclusion, it was found that after intravenous administration LHN-1 prevented experimental thrombosis as effectively as conventional heparin. However, the correlation between antithrombotic and haemorrhagic effects of LHN-1 was the same as that of conventional heparin. The corresponding relation in man remains to be determined.     

Neutralization of the antithrombotic effects of heparin and Fraxiparin by protamine sulfate.

In general, the in vitro anti Xa activity of low molecular weight heparins is neutralized to a lesser degree than the anti Xa activity of unfractionated heparin. To determine whether these differences occur in vivo, a rabbit stasis thrombosis model and a rat laser-induced thrombosis model were utilized. In the laser model, a similar degree of neutralization of the antithrombotic activity of heparin and Fraxiparin was obtained. However, in the stasis thrombosis model, significant antithrombotic activity of Fraxiparin remained after equigravimetric protamine administration. Ex vivo APTT, thrombin time, Heptest, amidolytic anti Xa and anti IIa assays were performed. A coefficient (r = .806) was obtained for the correlation of Heptest activity to antithrombotic effect in the stasis thrombosis model, while the coefficients obtained for the other tests ranged from .152-.570. However, after neutralization by protamine, the thrombin time exhibited the highest correlation coefficient (r = .685) between ex vivo activity and residual antithrombotic effect. Since Fraxiparin retains antithrombotic activity after protamine administration, clinical benefit may be observed for this low molecular weight heparin as compared to unfractionated heparin after neutralization.     

Monitoring heparin therapy: relationships between the activated partial thromboplastin time and heparin assays based on ex-vivo heparin samples

Five different APTT-reagents, two amidolytic anti-IIa assays, one amidolytic anti-Xa assay, and one coagulometric anti-Xa/anti-IIa assay were used to assess the effect of heparin in patients treated for venous thromboembolic disease. Good correlations were observed between log-transformed APTTs determined with the various reagents (correlation coefficients: 0.92-0.96). Nevertheless there were important differences in the slopes of the lines of relationship between the APTT reagents. Good correlations were observed between the anti-Xa and anti-IIa assay results (correlation coefficients: 0.92-0.97). However, the amidolytic anti-Xa activity was significantly higher (p less than 0.001) than the two amidolytic anti-IIa activities. Less good correlations were observed between the log-transformed APTTs and the anti-Xa or anti-IIa activities (correlation coefficients: 0.64-0.78). The correlations were improved by transforming the APTT into APTT-ratio, i.e. the ratio of the patient's APTT to the same patient's APTT after removal of heparin from the plasma sample by means of ECTEOLA-cellulose treatment. The correlation coefficients of log (APTT-ratio) with anti-Xa or anti-IIa ranged from 0.76 to 0.87. For both APTT and amidolytic heparin assay, the response to in vitro heparin was different from the response to ex vivo heparin. Therefore, equivalent therapeutic ranges should be assessed by using ex vivo samples rather than in vitro heparin. Because of the response differences between the APTT reagents, it is not adequate to define a therapeutic range for heparin therapy without specification of the reagent.     

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 vivo release of anti-Xa clotting activity by a heparin analogue

The parenteral injection of a semi-synthetic heparin analogue (SSHA) releases anti-Xa clotting activity, lipoprotein lipase activity and PF₄ antigen. The increased anti-Xa activity is not neutralized by PF₄ or protamine sulphate. A second injection of the drug after 90 minutes, or an increase in dose, does not increase the level of induced anti-Xa clotting activity. Possible mechanisms of action include the release by SSHA of endogenous glycosaminoglycans with anti-Xa activity, and interference by released lipoprotein lipase of a modulator of anti-Xa activity. It is concluded that a drug with weak anticoagulant activity in vitro may nevertheless have significant antithrombotic potential.     

In vitro neutralization of heparin in plasma prior to the activated partial thromboplastin time test: an assessment of four heparin antagonists and two anion exchange resins

This study was carried out to investigate the effects on the activated partial thromboplastin time test (APTT) when heparin in plasma was neutralized with protamine, Polybrene(R), poly-DL-lysine, or heparin neutralizing activity (HNA) extracted from platelets; or removed by means of the anion exchange resins TEAE cellulose or ECTEOLA cellulose. The effect on the APTT of adding the polycations protamine, Polybrene or poly-DL-lysine to citrated plasma was examined. The formation of heparin/polycation complexes was studied by means of their light scattering properties. The low yields of platelet HNA obtained excluded this from practical use as an in vitro heparin antagonist. ECTEOLA cellulose was unable to remove plasma heparin at levels as low as 1 U/ml by the technique employed. TEAE cellulose was able to efficiently remove at least 40 U of heparin from 1 ml of plasma but also caused a non-specific prolongation of the APTT. The polycations protamine, Polybrene, and poly-DL-lysine, possessed clot promoting activity at low concentrations and acted as anticoagulants in their own right at higher concentrations. At a plasma heparin concentration of 4 U/ml, protamine was the most efficient neutralizer of heparin, while at 10 U/ml, Polybrene was the most effective in this respect. It was concluded that care must be taken in the interpretation of the APTT after heparin neutralization or removal as heparin antagonist induced non-specific effects may be present.     

Comparative antithrombotic and hemorrhagic effects of dermatan sulfate, heparan sulfate and heparin

Dermatan sulfate and heparan sulfate are currently under development as potential antithrombotic drugs. In our studies we have evaluated the relative antithrombotic and bleeding effects of these two agents in comparison to heparin, the commonly used anticoagulant. In a rabbit model of stasis thrombosis, a 500 micrograms/kg IV dose of dermatan or heparan produced 50-60% inhibition of induced in vivo thrombosis. At 750 micrograms/kg, both agents produced greater than 75% inhibition of thrombosis. Ex vivo measurement of plasma samples obtained from these animals demonstrated variable clotting effects at the lower dose and a proportional increase in the clotting activity at the higher dose. No anti-Xa or anti-IIa activity was observed in any sample. In contrast, animals treated with only 100 micrograms/kg heparin showed complete inhibition of induced thrombosis with significant anti-Xa and anti-IIa activities as well as prolongation of the clotting assays (APTT, TT and HeptestR). In the hemorrhagic studies utilizing a rabbit ear blood loss model, a 5.0 mg/kg IV dose of dermatan or heparan produced much less blood loss than heparin. On a gravimetric basis, dermatan and heparan were 10 fold less hemorrhagic than heparin. These results indicate that the relative contribution of plasmatic and cellular sites to the mediation of the antithrombotic action of heparin, dermatan and heparan differ. Although the antithrombotic dosages of dermatan and heparan are higher than heparin, due to the different mechanisms of action of each agent, a better safety index may be provided by dermatan and heparan than heparin.     

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".     

Pharmacological profile of the chemically synthesized antithrombin III binding fragment of heparin (pentasaccharide) in rats

The antithrombotic and haemostatic effects of a pentasaccharide, the chemically synthesized antithrombin III (AT-III) binding fragment of heparin (PENTA), were investigated in rats in comparison with heparin. PENTA showed a dose-dependent antithrombotic effect in three thrombosis models in which thrombus formation was induced by different triggers. PENTA was consistently less potent than heparin in these models if doses were expressed in anti-Xa U/kg but PENTA showed more or less the same potency as heparin if doses were expressed in mg/kg. The antithrombotic effect of PENTA was strongly related to its anti-Xa activity as judged from its antithrombotic potency in the various models and from the time courses of both activities. PENTA caused a dose-dependent increase in blood loss in a bleeding model but the dose response curve was rather flat; the effect of PENTA on blood loss was small compared to that of heparin. The duration of action of PENTA as measured by the plasma anti-Xa levels was long compared to that of heparin and the duration of the antithrombotic effect was that expected on the basis of the plasma anti-Xa levels. Finally, PENTA showed comparable antithrombotic activity after s.c. and i.v. administration, as expected because of the approximately 100% bioavailability of the anti-Xa activity after s.c. administration.     

Ex vivo activity of heparin is not predictive of blood loss after neutralization by protamine.

To study whether the ex vivo activity of heparin and Fraxiparin correlates to and predicts the extent of blood loss induced by the heparins (pre- and post neutralization by protamine), a rat tail transection model and a rabbit ear bleeding model were used. In the rat model heparin (2 mg/kg i.v.) significantly prolonged the bleeding time, while this dose of Fraxiparin had no effect. In the rabbit ear blood loss model, heparin (2 mg/kg i.v.) produced significant increases in blood loss while Fraxiparin (2 mg/kg i.v.) produced approximately 30% of the blood loss induced by heparin. Equigravimetric protamine reduced the heparin-induced blood loss by approximately 50%, however, significant blood loss, thrombin time and Heptest activity remained. Heparin and Fraxiparin (3 mg/kg s.c.) did not cause any increased bleeding. While, all activities of heparin were completely neutralized by protamine, the Heptest activity of Fraxiparin was resistant to neutralization. The ex vivo activity of heparins after neutralization by protamine does not correlate to the extent of blood loss which suggests it may not be necessary to neutralize all ex vivo activities of the heparins to baseline values to be assured that blood loss is reversed.     

Time courses of the antithrombotic effects, bleeding enhancing effects and interactions with factors Xa and thrombin after administration of low molecular weight heparinoid Org 10172 or heparin to rats

Time response curves of the anti-thrombotic effects, bleeding enhancing effects, effects on APTT, anti-Xa activities, anti-thrombin activities and thrombin generation inhibitory activities of the low molecular weight heparinoid Org 10172 and heparin have been compared in rats. The time courses of these effects were similar for heparin but quite different for Org 10172. Org 10172 induced anti-thrombotic and anti-Xa effects which lasted approximately 3 times longer than those at the same anti-Xa doses of heparin, whereas the bleeding enhancing effects and effects on APTT of Org 10172 were of shorter duration than those of heparin. The half-life of the anti-thrombin effect after Org 10172 seemed somewhat longer than after heparin administration. Thrombin generation inhibition by Org 10172 showed a slightly longer duration than by heparin. The similarities between the time courses of the anti-thrombotic effect and the anti-Xa activity after Org 10172 administration suggest that the most appropriate parameter to monitor Org 10172 treatment is the plasma anti-Xa level.     

Low molecular weight protamine: a potential nontoxic heparin antagonist

Protamine sulfate is the universal clinical antagonist to heparin and is used routinely after cardiovascular surgery to neutralize the anticoagulant function of heparin. Its clinical use, however, is associated with adverse effects including idiosyncratic fatal reactions. An examination of the mechanism of heparin neutralization and protamine toxicity suggests that the reversal of heparin anticoagulation may only require a small arginine-rich fragment of protamine to electrostatically dissociate antithrombin III from its binding to a specific pentasaccharide sequence in heparin. A review of literature indicates that chain-shortened peptide fragments derived from their parent proteins are normally accompanied with significantly reduced antigenicity and immunogenicity, which are two primary contributing factors to protamine-induced life-threatening toxic effects via an immunoglobulin-mediated pathway. Based on these observations, we propose our general hypothesis: if a chain-shortened low molecular weight protamine fragment containing the heparin-neutralizing domain could be derived directly from a native protamine, it could be a potent and nontoxic heparin antagonist. In this article, we present our experimental results to support the above hypothesis. LMWP fragments containing an intact arginine sequence and an average molecular weight of approximately 1.1 kDa were prepared successfully by enzymatic digestion of native protamine with thermolysin. In vitro studies demonstrated that such LMWP fragments completely neutralized the anticoagulant functions of heparin, based on the anti-Xa chromogenic assay and aPTT clotting time assay. Our in vivo results indicated that while administration of protamine to mice led to obvious production of antiprotamine antibodies, injection of LMWP did not elicit any detectable immunogenic responses. In addition, the LMWP fragments showed a significantly reduced antigenicity or, in other words, cross-reactivity towards the mice antiprotamine antibodies produced by the administration of protamine.     

In vivo studies on the inhibition of coagulation by fractionated heparin and by a heparin analogue. II. Effects of a heparin analogue

SSHA, a semi-synthetic heparin analogue, and sodium heparin from porcine intestinal mucosa were injected subcutaneously into six healthy volunteers over a period of three days in a cross-over trial. Before injection and 2, 4, 6, 8 hrs afterwards, the heparin-like activity was measured with the APTT, the anti-Xa clotting test and two chromogenic substrate assays. The results show that SSHA mediates both anti-Xa and antithrombin activities in vivo. A comparison between the effects of SSHA and heparin is problematical due to the heterogeneity of different heparin preparations. Low doses of the analogue (45 mg s.c.) induced proportionally higher and longer lasting anti-Xa activities than higher doses (90 mg s.c.). Repeated injections of SSHA twice daily led to increasing effects on two tests for heparin-like activity, whereas two other tests remained unchanged. Both drugs were tolerated equally well, side effects were not detected. Clinical studies are required to demonstrate whether SSHA is similar or superior to low-dose heparin for use in thrombosis prophylaxis.     

Antithrombotic and anticoagulant activities of a low molecular weight fucoidan by the subcutaneous route

Fucoidans (high-molecular-weight sulfated polysaccharides extracted from brown seaweeds) have anticoagulant and antithrombotic effects. They inhibit thrombin by catalyzing both serpins (antithrombin and heparin cofactor II) according to their chemical structures and origins. In this study, a low-molecular-weight (LMW) fucoidan of 8 kDa was obtained by chemical degradation of a high-molecular-weight fraction. The antithrombotic and anticoagulant activities of this new compound were compared to those of a low-molecular-weight heparin (LMWH), dalteparin, following subcutaneous administration to rabbits. This LMW fucoidan exhibited dose-related venous antithrombotic activity, with an ED80 of about 20 mg/kg, 2 h after a single subcutaneous injection. Its activity was comparable to that of dalteparin (close to 200 anti-Xa IU/kg) and was maximal 30 min after a single subcutaneous injection. The activity remained stable (about 70%) from 1 to 4 h after injection, but disappeared by 8 h. The antithrombotic activity was not associated with either a prolongation of the thrombin clotting time (TCT) or an increase in anti-Xa activity, contrary to dalteparin. A slight prolongation of APTT occurred with both compounds. This venous antithrombotic activity was associated with a decrease in ex vivo thrombin generation and with a significant increase in the lag phase in a thrombin generation test. LMW fucoidan thus has potent antithrombotic activity and a potentially weaker haemorrhagic effect (i.e. a smaller effect on coagulation tests and a smaller prolongation of the bleeding time) than dalteparin.     

Studies on liposome-encapsulated heparin

In order to prolong the anticoagulant activity of heparin in vivo, attempts were made to encapsulate heparin into liposomes. Liposome-encapsulated heparin (lipo-heparin) prepared was large multilamellar vesicles (0.5-4.0 μm in diameter). The activity of lipo-heparin was 1.6-5.2x103 U/g lipid with recovery rate ranged between 0.4 to 1.3% and stable in saline at 4°C for at least two weeks. When intravenously administered into rats, the anticoagulant activity of lipo-heparin was significantly prolonged (approximately three times), as compared with that of untreated heparin. Furthermore, the activity of lipo-heparin could be neutralized by protamine sulfate. From these observations, it was concluded that liposome-encapsulation of heparin results in the prolonged anticoagulant effect in vivo and lipoheparin may be applicable for clinical use, after further studies on side effects of liposomes are completed.     

Does protamine chloride neutralize low molecular weight heparin sufficiently?

The heparin neutralizing properties of protamine chloride on conventional heparin (porcine mucosa) and on low molecular weight heparin (Kabi 2165) were studied in vitro. Protamine chloride neutralized 99% of the delaying effect of conventional heparin on the activated partial thromboplastin time, whereas only 70% of the effect of low molecular weight heparin was neutralized. The neutralizing effect of protamine chloride on the inhibition of factor Xa (clot test) was 95% for conventional heparin and 55% for low molecular weight heparin, whereas the effect of both heparin preparations on the thrombin inhibition could be completely neutralized. We conclude that conventional heparin is neutralized more effectively in vitro by protamine chloride than is the low molecular weight heparin. The findings do not exclude that protamine chloride is able to suppress in vivo bleedings caused by low molecular weight heparin.     

Neutralization of enoxaparine-induced bleeding by protamine sulfate

It has been suggested that protamine sulfate is a poor antidote for the bleeding side-effects of low molecular weight heparins (LMWHs) in vivo, since protamine sulfate does not completely neutralize the anti-factor Xa activity of LMWHs in vitro or ex vivo. Therefore, we performed experiments to compare directly the abilities of protamine sulfate to neutralize the anticoagulant activities of the LMWH, enoxaparine, and unfractionated heparin ex vivo, with its ability to neutralize the bleeding side-effects of both compounds in vivo. Bleeding was measured as the amount of blood lost from 5 cuts made in rabbits ears before and after treatment with enoxaparine or unfractionated heparin +/- protamine sulfate. Plasma anti-factor Xa and anti-thrombin activities ex vivo, were measured chromogenically. Doses of 400 and 1,500 anti-factor Xa U/kg of heparin and enoxaparine, respectively, were required to enhance blood loss to the same extent. Protamine sulfate completely neutralized blood loss induced by both compounds, but did not neutralize the anti-factor Xa nor antithrombin activities ex vivo. We conclude that protamine sulfate is an effective antidote for the bleeding side-effects of enoxaparine and unfractionated heparin, despite its inability to completely neutralize their anticoagulant activities.     

Effects of heparin, dermatan sulfate and of their association on the inhibition of venous thrombosis growth in the rabbit.

This study compares the ability of unfractionated heparin, of dermatan sulfate, and of their simultaneous administration delivered as continuous intravenous infusion or as a single bolus injection to inhibit the growth of a standardized venous thrombosis in the rabbit. When delivered as continuous intravenous infusion for 4 h, heparin and dermatan sulfate inhibited thrombus growth in a dose dependent manner. The maximum antithrombotic effect of heparin was achieved at the dose of 0.15 mg kg-1 h-1 (25 U kg-1 h-1) which generated a mean plasma concentration of 1.8 micrograms ml-1 (0.31 U ml-1) and a 1.8 fold prolongation of the activated partial thromboplastin time (APTT) in comparison to the pretreatment value. A comparable antithrombotic effect was obtained with dermatan sulfate at the dose of 2 mg kg-1 h-1. This dose generated a mean plasma concentration of 30 micrograms ml-1 and a 1.3 fold APTT prolongation. Increasing these doses up to 10 fold did not improve the antithrombotic effect which did not overpass 60-70% of the controls. When the compounds were delivered simultaneously, the maximum antithrombotic effect (64%) was obtained with the following association: 0.06 mg kg-1 h-1 (10 U kg-1 h-1) for heparin and 1 mg kg-1 h-1 for dermatan sulfate. Increasing these doses up to 4 to 5 fold did not improve the antithrombotic effect. Heparin, dermatan sulfate and the association of both were also delivered as single bolus injections and the resultant antithrombotic effect was determined 4 h after saline infusion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Inhibition of low molecular weight heparin by protamine chloride in vivo

To determine the antagonization of anticoagulant and lipolytic effects of a low molecular weight [LMW] heparin preparation protamine chloride was given intravenously after i.v. injection of LMW or normal heparin. The effects of normal heparin on factor Xa, thrombin, aPTT, lipoprotein [LPL] and hepatic triglyceride lipase [HTGL] activities were neutralized immediately by i.v. protamine. The inhibition of thrombin and aPTT by LMW heparin were also abolished, whereas the effects on LPL and HTGL were counteracted to 80% and on factor Xa only to 40% by i.v. protamine chloride. No rebound of the anticoagulant or lipolytic effect was detected. It is assumed that haemorrhagic complication during therapy can be antagonized by protamine chloride. The incomplete inhibitory effect of protamine chloride on LPL, HTGL and factor Xa activities of LMW heparin indicate that protamine chloride requires more than 14 saccharide units in the heparin molecule for interaction.     

Study on neutralization of low molecular weight heparin (LHG) by protamine sulfate and its neutralization characteristics.

The neutralizing effects of protamine sulfate (PS) on anticoagulant activities of low molecular weight heparin (LHG) and conventional sodium heparin (Heparin) were investigated. The in vitro anti-factor Xa and APTT-prolonging activities of Heparin were almost completely neutralized by PS, whereas the activities of LHG remained partially intact in the presence of PS. Crossed immunoelectrophoresis of antithrombin III (AT III) and affinity chromatography of LHG- and Heparin-cellulose showed that AT III was substantially less dissociated from its binding to LHG than to Heparin in the presence of PS. As in vitro, the in vivo anticoagulant activities of Heparin administered i.v. to rabbits were almost completely neutralized by PS, while the anti-factor Xa and APTT-prolonging activities of LHG remained partially intact in the presence of PS. The thrombin time-prolonging activity of LHG, however, was completely inhibited by PS. Since the bleeding effect of Heparin or LHG is considered mainly due to its anti-thrombin activity, PS may be used as an agent to neutralize LHG, as in the case of Heparin, when bleeding happens to occur during LHG treatment.