Enhanced prothrombin-converting activity and factor Xa binding of platelets activated by the alternative complement pathway

Platelet prothrombin-converting activity and factor Xa binding were studied after exposure of human platelet rich plasma (PRP) to various conditions leading to platelet activation. Zymosan resulted in increased platelet-bound C3, enhanced prothrombin-converting activity and increased factor Xa binding. Similar findings were observed with normal platelets resuspended in factor XII-deficient plasma. The combined use of zymosan and thrombin to activate platelets resulted in synergistic prothrombin-converting activity and factor Xa binding. In contrast, no synergism was obtained with the concomitant use of zymosan and collagen, suggesting that collagen and zymosan share the same pathway for platelet activation. Heterologous antibody to factor V completely inhibited the platelet prothrombin-converting activity for all modes of platelet activation, indicating that this activity is mediated by factor V.     

Simulation model for thrombin generation in plasma.

A simulation model for the production of thrombin in plasma is presented. Values of the reaction rate constants as determined in purified systems are used and the model is tested by comparison of simulations of factor Xa, factor Va and thrombin generation curves with experimental data obtained in thromboplastin-activated plasma. Simulations of the effect of hirudin indicate that factor V is predominantly activated by thrombin and not by factor Xa. The model predicts a threshold value for the factor Xa production which, if exceeded, results in explosive and complete activation of prothrombinase. The dependence of this threshold value on different negative feedback reactions, e.g. the inactivation of thrombin and factor Xa by antithrombin III (+ heparin), is investigated. The threshold value, for control plasma in the range of 1-10 pM total factor Xa production, can be raised two orders of magnitude by accelerated inactivation of factor Xa and prothrombinase but is hardly affected by a tenfold increase in the rate of thrombin inactivation or by increased production of activated protein C. This latter effect, however, results in a more gradual input-response relation between factor Xa input and the extent of prothrombinase activation.     

The inhibition of the anticoagulant activity of heparin by platelets, brain phospholipids, and tissue factor

Platelets and phospholipids have been shown to protect factor Xa from inhibition by the heparin--antithrombin III complex. The studies reported herein investigated the effects of gel filtered platelets, activated platelets, brain phospholipids (cephalin), and brain tissue factor on the inactivation of thrombin and factor Xa by the heparin--antithrombin III complex. In addition, the relative anticoagulant effects of heparin on the extrinsic and intrinsic coagulation pathways were investigated. Our results suggest that gel filtered platelets, activated platelets, cephalin and tissue factor protect thrombin, as well as factor Xa, from inactivation by the heparin--antithrombin III complex. Tissue factor had the greatest anti-heparin activity. Activated platelets, gel filtered platelets, cephalin and tissue factor did not alter the protease--antithrombin III reaction rates measured in the absence of heparin. These observations are consistent with the hypothesis that platelets, brain phospholipids, and tissue factor, in the presence of calcium, partition heparin from antithrombin III, and thus prevent full expression of the antithrombin III-dependent anticoagulant activity of heparin.     

Anticoagulant and fibrinolytic activities are promoted, not retarded, in vivo after thrombin generation in the presence of a monoclonal antibody that inhibits activation of protein C.

This study examines the assumption that both the anticoagulant and fibrinolytic activity that follow the generation of thrombin induced by infusion of factor Xa/PCPS are due to generation of activated protein C. Untreated controls or animals given unrelated antibody were compared with animals pretreated with a specific monoclonal antibody to protein C (HPC4). Compared with untreated controls excess HPC4 substantially reduced the level of protein C activation as observed by protein C immunoblotting and enzyme-linked immunosorbent assay for antitrypsin/activated protein C complexes. Despite this, the anticoagulant activity as reflected by the decline of factors Va and VIIIa levels (as observed by coagulation assays and by factor V immunoblotting) was significantly greater than controls. The fibrinolytic activity (as observed by assays of tissue plasminogen activator, D-Dimer, alpha 2-antiplasmin) also was significantly greater than controls. We conclude that neutralization of the protein C anticoagulant system while resulting in a significantly more intense coagulant response to Xa/PCPS does not preclude inactivation of factors Va and VIIIa and the full expression of the fibrinolytic response. We conclude further that after thrombin generation in vivo, protein C activation is not a prerequisite for the promotion of the fibrinolytic response previously observed, and that the inactivation of factors Va/VIIIa may be mediated by enzymes other than activated protein C. The reduction in alpha 2-antiplasmin levels in association with increased tissue plasminogen activator activity suggests that plasmin is a likely candidate.     

Experiments on the Nature of the Prothrombin-Converting Principle: Alteration of Proaccelerin Thrombin

An incubation mixture of activated Stuart factor, calcium, phospholipid and proaccelerin caused the generation of thrombin from prothrombin. The activity of this prothrombin- converting principle was measured by the rate at which it converted prothrombin to thrombin. In the absence of thrombin in the incubation mixture, a lag phase, following addition of the prothrombin-converting principle to prothrombin, was observed before thrombin formation occurred. But when a trace of thrombin was added to the incubation mixture, it converted the principle into an active form, causing the immediate formation of thrombin from prothrombin without any delay. It was demonstrated that thrombin had this action upon the prothrombin-converting principle by changing proaccelerin into a more active form.
Thrombin-treated proaccelerin would not convert prothrombin to thrombin in the absence of activated Stuart factor, indicating that it is not, by itself, the prothrombin-converting principle.
By purification of the thrombin preparation, and the use of hirudin, it was shown that the action of thrombin on proaccelerin was due to thrombin itself and not to activated Stuart factor or other contaminating substances in the thrombin preparation.     

Factors IXa and Xa play distinct roles in tissue factor-dependent initiation of coagulation

Tissue factor is the major initiator of coagulation. Both factor IX and factor X are activated by the complex of factor VIIa and tissue factor (VIIa/TF). The goal of this study was to determine the specific roles of factors IXa and Xa in initiating coagulation. We used a model system of in vitro coagulation initiated by VIIa/TF and that included unactivated platelets and plasma concentrations of factors II, V, VIII, IX, and X, tissue factor pathway inhibitor, and antithrombin III. In some cases, factor IX and/or factor X were activated by tissue factor- bearing monocytes, but in some experiments, picomolar concentrations of preactivated factor IX or factor X were used to initiate the reactions. Timed samples were assayed for both platelet activation and thrombin activity. Factor Xa was 10 times more potent than factor IXa in initiating platelet activation, but factor IXa was much more effective in promoting thrombin generation than was factor Xa. In the presence of VIIa/TF, factor X was required for both platelet activation and thrombin generation, while factor IX was only required for thrombin generation. We conclude that VIIa/TF-activated factors IXa and Xa have distinct physiologic roles. The main role of factor Xa that is initially activated by VIIa/TF is to activate platelets by generating an initial, small amount of thrombin in the vicinity of platelets. Factor IXa, on the other hand, enhances thrombin generation by providing factor Xa on the platelet surface, leading to prothrombinase formation. Only tiny amounts of factors IX and X need to be activated by VIIa/TF to perform these distinct functions. Our experiments show that initiation of coagulation is highly dependent on activation of small amounts of factors IXa and Xa in proximity to platelet surfaces and that these factors play distinct roles in subsequent events, leading to an explosion of thrombin generation. Furthermore, the specific roles of factors IXa and Xa generated by VIIa/TF are not necessarily reflected by the kinetics of factor IXa and Xa generation.     

The effect of aggregation and release on platelet prothrombin-converting activity.

Platelets provide a procoagulant activity for the conversion of prothrombin to thrombin during normal hemostatis. This activity designated as platelet prothrombin-converting activity (PPCA) was monitored as rate of thrombin production in a two-stage assay using gel-filtered bovine platelets, factor Xa, and prothrombin. Expression of PPCA was not associated with ADP-induced release or platelet shape change but was associated with aggregation. Release of the contents of dense bodies, measured by release of 14C-5-hydroxytryptamine, was not required for expression of PPCA during platelet aggregation. During the PPCA assay, 5-hydroxytrypamine was released, but only after onset of thrombin production. Furthermore, the release of 5-hydroxytryptamine was retarded during the assay by the addition of 2 mM theophylline and 100 nM prostaglandin E1 without a comparable reduction in PPCA. In addition, 125I-factor-Xa was bound in greater amounts to platelets (aspirin-treated) after ADP-induced aggregation (without detectable release) than to unactivated control platelets. Finally, the PPCA of the ADP-activated platelets was saturated with respect to factors Xa and Va at less than 1 nM concentrations, indicating that the aggregation induced by ADP leads to the exposure of specific procoagulant sites by some process other than dense body secretion.     

Human coagulation factor Va is a cofactor for the activation of protein C.

During blood clotting in vitro, protein C is converted in part to protein Ca, Protein Ca, in turn, inactivates factor Va. This is evidenced by the rapid inactivation of factor Va coagulant activity after clot formation which is associated with the cleavage of the Mr 110,000 peptide of factor Va. When exogenous factor Va is added to serum, it is inactivated only after a lag of 10-20 min. Using purified coagulation factors in the presence of EDTA, we demonstrated that factor Va enhances the rate of protein C activation by thrombin by 50-fold. The Km for factor Va in the reaction is 14 nM, 100 times higher than its Km for accelerating platelet surface prothrombin activation by factor Xa. By this mechanism, factor Va can act as a procoagulant as well as limit dissemination of the coagulation process through the activation of protein C and the subsequent inactivation of both factor Va and factor VIIIa.     

The role of natural anticoagulants in the pathogenesis and management of systemic activation of coagulation and inflammation in critically ill patients

Critically ill patients often have systemic activation of both inflammatory systems and coagulation. Increasing evidence points to an extensive cross-talk between these two systems, whereby inflammation leads to activation of coagulation and coagulation considerably affects inflammatory activity. The intricate relationship between inflammation and coagulation may have major consequences for the pathogenesis of microvascular failure and subsequent multiple organ failure, as a result of severe infection and the associated systemic inflammatory response. Molecular pathways that contribute to inflammation-induced activation of coagulation have been precisely identified. Activation of the coagulation system and ensuing thrombin generation is dependent on an interleukin-6-induced expression of tissue factor on activated mononuclear cells and endothelial cells and is insufficiently counteracted by tissue factor pathway inhibitor. Simultaneously, endothelial-bound anticoagulant mechanisms, in particular the protein C system and the antithrombin system, are shut off by proinflammatory cytokines. Modulation of inflammatory activity by activation of coagulation also occurs by various mechanisms. Activated coagulation proteases, such as the tissue factor-factor VIIa complex, factor Xa, and thrombin, can bind to protease-activated receptors on various cells, and the ensuing intracellular signaling leads to increased production of proinflammatory cytokines and chemokines. Activated protein C can bind to the protein C receptor on endothelial cells and mononuclear cells, thereby affecting NF-kappaB nuclear translocation and subsequently influencing inflammatory gene expression and inhibition of tissue factor expression on mononuclear cells. Observations in experimental models of targeted disruption of the protein C gene and restoration of the downregulated protein C pathway by administration of recombinant activated protein C support this notion.     

Linearized model for the initiation of factor Va, and thrombin generation.

A simple model of the initiation of thrombin formation in plasma as a response to factor Xa generation was constructed. In this model factor Xa is considered as an input with a constant concentration. Substrate depletion and inactivation by activated protein C are neglected. The resulting linear model allows a closed form solution by standard methods. With values of the reaction rate constants, as determined in purified systems, this model predicts a highly explosive and complete activation of factor V and prothrombin as a response to any given (steady state) factor Xa concentration even in situations where prothrombinase and(/or) thrombin are rapidly inactivated. However, the time delay to rapid thrombin production becomes longer at lower factor Xa concentrations. Analysis of this time delay as a function of the factor Xa concentration indicates that the gain of the feedback loop of factor V activation by thrombin is so high that the contribution of factor V activation by factor Xa is relatively unimportant for factor Xa concentrations in the nanomolar range. It appears that the time lag is mainly determined by the gain of this feedback loop: similar proportional reductions of each of these reaction rates causes a similar effect. The effects of moderately enhanced inhibition rates of thrombin and prothrombinase on the time delay depend strongly on factor Xa concentration. Only a minor prolongation of the delay is predicted for factor Xa concentrations in the nanomolar range, but for factor Xa concentrations in the 1-10 pM range, the enhanced decay will cause considerable delays. Simultaneous reduction of the turnover rate of prothrombinase results in much larger delays for the entire range of factor Xa concentrations.     

Factor VIII: structure and function in blood clotting

Factor VIII (antihemophilic factor) is the protein that is deficient or defective in patients with classical hemophilia and Von Willebrand syndrome. Factor VIII in plasma is thought to be associated in a complex with the highest molecular weight multimers of another glycoprotein, Von Willebrand protein. Highly purified human factor VIII appears to have an Mr of between 200,000 and 300,000 and to consist of several polypeptide chains. The concentration of factor VIII in plasma is around 100-200 ng/ml, equivalent to around 1 nM. The purified proteins retain one or more of the known properties of factor VIII, including the acceleration of factor IXa-mediated activation of factor X, ability to be activated by thrombin and factor Xa, inactivation by activated protein C, and by human antibodies to factor VIII. Among the known clotting factors, factors VIII and V are exceptional in not possessing enzymatic activity. Factors IXa and VIII and X appear to form a functional complex, all of which need to be present and active simultaneously for optimal activation of factor X. The mechanism by which factor VIII promotes activation of factor X by factor IXa is not known, but the major effect is to increase the rate of the reaction. Following treatment of factor VIII with thrombin, a new and smaller polypeptide Mr around 70,000 +/- 5,000 is produced. Factors IXa and Xa also have been reported to activate factor VIII. It is not known whether limited proteolytic cleavage is required absolutely for the expression of factor VIII activity or if it only increases an activity already expressed by the uncleaved protein. Factor VIII is inactivated by thrombin and by activated protein C. Thus, factor VIII can be modulated by at least four of the serine proteases in the clotting system. A major goal for future research is to increase our understanding of the role in blood clotting played by factor VIII, and to apply this information to clinical problems which result from inherited abnormalities of factor VIII.     

Characterization of a genetically engineered inactivation-resistant coagulation factor VIIIa

Individuals with hemophilia A require frequent infusion of preparations of coagulation factor VIII. The activity of factor VIII (FVIII) as a cofactor for factor IXa in the coagulation cascade is limited by its instability after activation by thrombin. Activation of FVIII occurs through proteolytic cleavage and generates an unstable FVIII heterotrimer that is subject to rapid dissociation of its subunits. In addition, further proteolytic cleavage by thrombin, factor Xa, factor IXa, and activated protein C can lead to inactivation. We have engineered and characterized a FVIII protein, IR8, that has enhanced in vitro stability of FVIII activity due to resistance to subunit dissociation and proteolytic inactivation. FVIII was genetically engineered by deletion of residues 794-1689 so that the A2 domain is covalently attached to the light chain. Missense mutations at thrombin and activated protein C inactivation cleavage sites provided resistance to proteolysis, resulting in a single-chain protein that has maximal activity after a single cleavage after arginine-372. The specific activity of partially purified protein produced in transfected COS-1 monkey cells was 5-fold higher than wild-type (WT) FVIII. Whereas WT FVIII was inactivated by thrombin after 10 min in vitro, IR8 still retained 38% of peak activity after 4 hr. Whereas binding of IR8 to von Willebrand factor (vWF) was reduced 10-fold compared with WT FVIII, in the presence of an anti-light chain antibody, ESH8, binding of IR8 to vWF increased 5-fold. These results demonstrate that residues 1690–2332 of FVIII are sufficient to support high-affinity vWF binding. Whereas ESH8 inhibited WT factor VIII activity, IR8 retained its activity in the presence of ESH8. We propose that resistance to A2 subunit dissociation abrogates inhibition by the ESH8 antibody. The stable FVIIIa described here provides the opportunity to study the activated form of this critical coagulation factor and demonstrates that proteins can be improved by rationale design through genetic engineering technology.     

A comparison of phospholipid and platelets in the activation of human factor VIII by thrombin and factor Xa, and in the activation of factor X

Two aspects of the activation of factor X by the intrinsic clotting pathway have been studied in purified human systems, in the presence of either purified phosphatidylserine:phosphatidylcholine vesicles (PS:PC) or platelets activated with ionophore A23187: (1) the activation of factor VIII by factor Xa and by thrombin, and (2) the activation of factor X by the factor IXa/VIIIa complex. Factor VIII activation by thrombin was unaffected in either rate or extent by the presence of PS:PC or activated platelets. In contrast, factor VIII activation by factor Xa required either PS:PC or platelets. The products of optimal factor VIII activation by the two enzymes, designated factor VIIIa(T) and factor VIIIa(Xa), are kinetically different in the activation of factor X by factor IXa, factor VIIIa(T) being approximately twice as active (in factor X activation) as factor VIIIa(Xa) in the presence of PS:PC or platelets. Factor VIIIa(Xa) can be converted to the more active VIIIa(T) by thrombin treatment, but the activity of factor VIIIa(T) is unchanged by factor Xa treatment. Factor X activation was also studied with optimally activated factor VIIIa(T), in the presence of PS:PC or activated platelets, as a function of factor IXa concentration in order to determine the apparent dissociation constant for the factor IXa-VIIIa interaction in the two cases. Activated platelets increased the apparent affinity more than fivefold.     

Activated clotting factors in factor IX concentrates.

The precise quantitation of activated factors in human factor IX concentrates has been accomplished with the use of recently developed, specific assays for factors IXa, Xa, and thrombin. The assay for factor IXa, which measures the initial rate of 3H-factor-X activation, was shown to be specific for factor IXa in the concentrates. Activated factor IX concentrates contained 1.0-2.3 microgram/ml of factor IXa; whereas the assays of unactivated concentrates were negative (less than 0.2 microgram/ml). The assays of factor Xa and thrombin, which measure the initial rate of p-nitroaniline release from S-2222 and S-2238, respectively, showed similar small amounts of factor Xa (4-34 ng/ml) and thrombin (12-76 ng/ml) in the activated and unactivated concentrates. The nonactivated partial thromboplastin time of the concentrates correlated significantly with the factor IXa content, but not with factor Xa or thrombin. Antithrombin III antigen in 3 of 4 concentrates was several-fold higher than antithrombin III activity, suggesting the presence of antithrombin III complexed with activated factors. These results support the hypothesis that the degree of activation of factor IX concentrates is related primarily to the concentration of factor IXa, which may be responsible for the thrombogenicity of these concentrates in some clinical settings.     

Activated protein C cleaves factor Va more efficiently on endothelium than on platelet surfaces

The protein C/protein S system is known to regulate thrombin generation in vivo by cleaving factors Va and VIIIa. We have examined the activity of activated protein C in several tissue factor-initiated models of coagulation. We used 4 models: monocytes as the tissue factor source with platelets as the thrombin-generating surface; endothelial cells as the tissue factor source with platelets as the thrombin-generating surface; endothelial cells as both the tissue factor source and the thrombin-generating surface; and relipidated tissue factor with lipid vesicles providing the surface for thrombin generation. With the lipid surface, activated protein C dose-dependently reduced thrombin generation. Similarly, when endothelial cells provided the only surface for thrombin generation, activated protein C dose-dependently decreased thrombin generation significantly. By contrast, whenever platelets were present, activated protein C only minimally affected the amount of thrombin generated. When endothelial cells were the tissue factor source with platelets providing the surface for thrombin generation, activated protein C did increase the time until the burst of thrombin generation but had minimal effects on the total amount of thrombin generated. Activated protein C had essentially no effect on thrombin generation when monocytes were the tissue factor source with platelets providing the surface for thrombin generation. From the studies reported here, we conclude that in vivo, despite the important role of the protein C system in regulating thrombosis, activated protein C does not serve as a primary regulator of platelet-dependent thrombin generation.     

Deficiency of factor Xa-factor Va binding sites on the platelets of a patient with a bleeding disorder.

Factor V (Va) is essential for binding of factor Xa to the surface of platelets. After thrombin treatment, normal platelets release at least five times more factor Va activity than is required for maximal factor Xa binding. The concentration of factor V activity obtained after thrombin stimulation of 10(7) normal platelets is sufficient to allow half-maximal factor Xa binding to 10(8) platelets (10% normal, 90% factor-V deficient). Therefore, factor Va activity is not limiting in platelet-surface factor Xa binding and prothrombin activation in normal platelets; some other components limit the number of binding sites. We report studies of a patient (M.S.) with a moderate to severe bleeding abnormality whose platelets are deficient in the platelet-surface component required for the factor Va-factor Xa binding. The patient's platelet factor Va activity released after thrombin treatment is normal, but factor Xa binding is 20%-25% of control values at saturation. Abnormal prothrombin consumption in a patient with normal plasma coagulation factors and platelet function suggests a disorder in platelet-surface thrombin formation.     

The importance of thrombin inhibition for the expression of the anticoagulant activities of heparin, dermatan sulphate, low molecular weight heparin and pentosan polysulphate

The effects of standard heparin, three low molecular weight derivatives of heparin, dermatan sulphate and pentosan polysulphate on the intrinsic coagulation pathway were compared in order to evaluate the contributions of the anti-factor Xa and anti-thrombin activities to their anticoagulant activities. The anticoagulant potency was measured by the ability of each sulphated polysaccharide to inhibit the generation of thrombin activity in plasma. Similarly, the ability of the six sulphated polysaccharides to enhance the rates of inactivation either factor Xa or thrombin in defibrinated plasma containing calcium chloride and cephalin were also determined. Standard heparin was the only sulphated polysaccharide that could equally inhibit thrombin generation and enhance the inactivation of factor Xa and thrombin by plasma. Dermatan sulphate and pentosan polysulphate were more effective as inhibitors of thrombin generation than potentiators of factor Xa inactivation. The two smallest derivatives of heparin, which had high anti-factor Xa (but low antithrombin) activity, were the poorest inhibitors of thrombin generation. Our results therefore suggest that only sulphated polysaccharides that enhance the inactivation of thrombin by plasma and/or inhibit the generation of thrombin activity in plasma are good anticoagulants. These two activities of sulphated polysaccharides appear to be good predictors of the relative antithrombotic potency in vivo.     

The effect of platelet factor 4 (PF4) on assays of plasma heparin

Platelet factor 4 (PF4) is a potent antiheparin in vitro. In view of the large amount of PF4 secreted from platelet alpha-granules during routine blood collection and processing techniques, the potential significance of this release was investigated using three measurements of heparin activity: the activated partial thromboplastin time (aPTT), the thrombin time, and factor Xa inactivation using the chromogenic substrate S2222 for assay of factor Xa. The results demonstrate that purified PF4 neutralizes heparin activity when added in increasing amounts to normal platelet-poor plasma containing a fixed concentration of commercial porcine gut mucosal heparin. This effect was seen when assaying heparin activity by all three methods. In addition, when heparin was added in increasing concentrations to pooled plasma samples that were collected from normal volunteers, there was neutralization of heparin activity in blood samples collected by routine citrate anticoagulation (CIT60) in comparison to blood samples collected simultaneously with platelet secretion inhibiting agents added to the anticoagulant (CIT+). This effect was seen when assaying heparin by the aPTT and thrombin time. These data confirm that both purified and secreted PF4 have significant antiheparin activity when heparin is added in vitro to normal plasma. Neutralization of circulating heparin by PF4 secreted during blood collection from anticoagulated patients could result in underestimation of the actual in vivo heparin concentration. In order to evaluate the significance of this effect, purified PF4 was added to plasma collected from heparinized patients and again PF4 neutralized heparin activity. This was seen, however, only when heparin activity was measured by the thrombin time or Xa inactivation assays. There was minimal shortening of the aPTT when PF4 was added in final concentrations up to 1000 ng/ml. When blood samples were simultaneously collected from anticoagulated patients by both routine and special collection methods, these results were confirmed. There was a significant difference between heparin activities measured in the CIT+ (secreted PF4 58 ng/ml) and CIT60 (secreted PF4 1074 ng/ml) plasma samples by both thrombin time and Xa inactivation. There was no difference, however, in the aPT when both types of plasma samples were simultaneously collected and assayed for each anticoagulated patient. This suggests that there may be circulating heparin fractions which can prolong the aPTT but which do not interact with PF4.(ABSTRACT TRUNCATED AT 400 WORDS)     

Orgaran (Org 10172): its pharmacological profile in experimental models.

Orgaran is a mixture of glycosaminoglycans extracted from animal mucosa. It consists of heparan, dermatan and chondroitin sulfate; a small proportion of heparan sulfate (4%) has high affinity for antithrombin III (AT III). Orgaran is devoid of heparin or heparin fragments. Orgaran catalyses the inactivation of factor Xa and thrombin. Compared to heparin and most low-molecular-weight heparins, Orgaran has a much higher anti-Xa/anti-IIa ratio. The inactivation of factor Xa is mediated by AT III and that of thrombin by both AT III and heparin cofactor II. Compared to heparin, which is a strong inhibitor of thrombin generation, Orgaran has only moderate inhibitory effects on thrombin generation. Orgaran shows minimal or no effects on platelet function in vitro or in vivo. It inhibits the formation of various types of thrombi (clot-like and mixed thrombi) with approximately the same potency as heparin. Both the high- and low-affinity fraction for AT III contribute to the antithrombotic activity. In contrast to heparin, Orgaran does not inhibit platelet deposition in experimental mixed thrombi unless very high doses of the heparinoid are used. Orgaran is more efficacious than heparin in preventing the extension of established venous thrombosis. Orgaran promotes less bleeding-enhancing activity than heparin in various experimental models. In addition, compared to heparin, it has only minimal effects on platelet degranulation during hemostatic plug formation.(ABSTRACT TRUNCATED AT 250 WORDS)