Fibrin monomer protects thrombin from inactivation by heparin-antithrombin III: implications for heparin efficacy.

Fibrin II monomer has a dramatic inhibitory effect on the rate of heparin-catalyzed inactivation of human alpha-thrombin by antithrombin III. At 6 microM fibrin II monomer, equivalent to the concentration of fibrinogen in plasma, the second-order rate constant was reduced by a factor of 308--from 2.05 x 10(8) M-1.s-1 to 6.65 x 10(5) M-1.s-1. Fibrin II monomer minimally affected the uncatalyzed rate of thrombin inactivation showing a reduction in the second-order rate constant by a factor of only 1.6. Fibrinogen and the product of plasmin degradation of fibrinogen, fragment E, at 6 microM concentrations also decreased the second-order rate constant for heparin-catalyzed thrombin inactivation, but by factors of only 2.7 and 1.9, respectively. On the basis of these observations it is proposed that protection of thrombin from inactivation by heparin-antithrombin III by fibrin II monomer can explain the limited efficacy of heparin in preventing coronary reocclusion in patients treated with tissue plasminogen activator and other fibrinolytic agents.     

Alpha-2-macroglobulin may provide protection from thromboembolic events in antithrombin III-deficient children.

Antithrombin III (ATIII) deficiency has been implicated in adults as a predisposing factor to thrombosis; however, thromboembolic complications are rare in children with the same deficiency. We hypothesized that because of the elevated levels of plasma alpha-2-macroglobulin (alpha 2M) throughout childhood, plasmas of ATIII-deficient children inhibit thrombin more efficiently than those of ATIII-deficient adults. In total, 14 ATIII-deficient adults (ages 25 to 46 years), 13 ATIII-deficient children (ages 2 to 13 years), 9 normal children (ages 3 to 15 years), and 16 normal adults were studied. We measured thrombin inhibition in these plasmas, as well as the contributions of ATIII, alpha 2M, and heparin cofactor II (HCII) as thrombin inhibitors in each plasma. 125I-alpha-thrombin, 25 nmol/L, was added to each plasma (defibrinated with Arvin at 37 degrees C), and 90 seconds later the free thrombin and thrombin-inhibitor complexes were quantitated after sodium dodecyl sulfate-polyacrylamide gel electrophoresis, autoradiography, and densitometric scanning. Plasma from ATIII-deficient adults inhibited significantly less thrombin (12.8 +/- 0.6 nmol/L) than both normal adults (16.1 +/- 0.3 nmol/L, P less than .01), normal children (15.7 +/- 0.4 nmol/L, P less than .01), or ATIII-deficient children (15.5 +/- 0.3 nmol/L, P less than .01). There was no significant difference between the total concentration of thrombin inhibited by ATIII-deficient children and either normal adult or normal children groups. In addition, plasmas of ATIII-deficient children inhibited thrombin significantly more efficiently than plasma of ATIII-deficient adults (P less than .01). In the ATIII-deficient patients there was a significant correlation between the alpha 2M level and ability to inhibit thrombin (P less than .01), but no correlation between either ATIII or HCII levels and thrombin inhibition. On the addition of heparin (0.4 U/mL) to plasma, all four types of plasma inhibited thrombin to the same extent. Although ATIII was the predominant inhibitor in all heparinized plasmas, HCII inhibited more thrombin in the ATIII-deficient patients than in normal patients (2.8 +/- 0.3 v 1.2 +/- 0.2 nmol/L, P less than .01). We hypothesize that the lower risk of thromboembolic complications in ATIII-deficient children may be due in part to the protective effect of elevated alpha 2M levels during childhood.     

Interaction of protamine sulfate with thrombin

Protamine sulfate (salmine), a basic protein with a molecular weight of 4,626 +/- 109, is a known antiheparin agent which in the absence of heparin demonstrates an anticoagulant activity. To date, much work has been done to elucidate the interaction of heparin with thrombin and its physiologic inhibitor, Antithrombin III (ATIII). Little is known, however, about the mechanism of anticoagulant action of protamine sulfate and its mode of thrombin inactivation. We provide information about the interaction of protamine sulfate with purified, labeled thrombin and ATIII through binding experiments in which protamine is shown to inhibit the inactivation of thrombin by ATIII. Furthermore, we show in clotting assays that protamine sulfate has an inhibitory effect on thrombin in the conversion of fibrinogen to fibrin, and that this inhibition is concentration dependent, partial, and reversible.     

Flow and the inhibition of prothrombinase by antithrombin III and heparin

Inhibition of prothrombinase by antithrombin III (ATIII) and heparin was investigated in a continuous-flow system. Phospholipid-coated capillaries, containing phospholipid-bound factor Xa and factor Va, were perfused with 1.0 mumol/L prothrombin and 0.5 nmol/L factor Va. At 25 degrees C and a flow rate of 32 microL/min (shear rate 28 seconds-1) the steady-state rates of prothrombin conversion depended linearly on the surface concentration of prothrombinase up to 2 fmol/cm2. The rate of thrombin generation was 952 +/- 43 (SE) mol/min/mol prothrombinase. When ATIII was included in the perfusate for 10 minutes, the free thrombin concentration at the outlet of the capillary was markedly reduced: a 50% neutralization was obtained at 0.7 mumol/L ATIII. However, the prothrombinase activity was not inhibited, as could be established after a subsequent perfusion with prothrombin and factor Va. At an ATIII concentration typical of normal plasma (2 mumol/L) a slight neutralization of prothrombinase was observed: 10% neutralization following a 10-minute perfusion. During a perfusion with ATIII in the absence of prothrombin, or in its presence with hirudin (2 mumol/L) also included in the perfusate, a more pronounced neutralization of prothrombinase was observed: 40% residual activity was obtained after a 10-minute perfusion. From this observation the suggestion comes forward that thrombin, continuously produced at the surface, consumes ATIII in the boundary layer. In this case the true ATIII concentration in the vicinity of surface-bound prothrombinase will be but a small fraction of the initial ATIII concentration in the bulk fluid. Unfractionated heparin and an ultra-low molecular weight heparin (pentasaccharide) did enhance the ATIII-dependent neutralization of prothrombinase, but to a much lesser extent than observed with small unilaminar phospholipid vesicles as the catalytic sites for prothrombinase assembly. The findings reported here support the notion that regulation of prothrombinase by heparin under in vivo conditions occurs at the stage of its formation, ie, through inhibition of free factor Xa and/or the generation of factor Va, rather than by direct inhibition of the prothrombinase activity.     

Thrombolytic therapy with tissue plasminogen activator or streptokinase induces transient thrombin activity

We have determined the plasma level of fibrinopeptide A as a specific index of thrombin activity during the infusion of a thrombolytic agent in patients with acute myocardial infarction. Peripheral venous plasma levels of fibrinopeptide A increased following the initiation of thrombolytic therapy from 2.7 nmol/L to a peak of 13.0 nmol/L at 30 minutes with streptokinase and from 1.1 nmol/L to a peak of 10.7 nmol/L at 90 minutes with tissue plasminogen activator. The amount of fibrinogen converted to fibrin I was determined by integration of the plasma level of fibrinopeptide A over time. The amount of fibrin I formed over the five-hour period from the start of drug infusion was approximately 10 mg/dL in response to either streptokinase or recombinant tissue plasminogen activator. We conclude that activation of coagulation occurs in response to thrombolytic therapy despite heparin administration. This thrombin action, though transient, would be sufficient to cause rethrombosis if localized and incompletely opposed by fibrinolytic activity.     

Regulation by alpha 2-antiplasmin and fibrin of the activation of plasminogen with recombinant staphylokinase in plasma

The effects of alpha 2-antiplasmin and fibrin on the activation of plasminogen by recombinant staphylokinase (STAR) were studied in an effort to elucidate further the molecular basis of the fibrin- specificity of this fibrinolytic agent. In purified systems consisting of 1.5 mumol/L intact or low-M(r) plasminogen and 3 mumol/L alpha 2- antiplasmin, at 37 degrees C and in the absence of fibrin, STAR did not induce plasminogen activation and plasmin-alpha 2-antiplasmin complex (PAP) formation. Addition of a purified fibrin clot (30% vol at a concentration of 3 mg/mL) to mixtures containing intact plasminogen caused approximately 40% plasminogen activation within 2 hours, whereas in mixtures containing low-M(r) plasminogen, no activation was observed. In contrast, 10 nmol/L streptokinase (SK) induced 74% to 100% plasminogen activation within 2 hours in mixtures containing either intact or low-M(r) plasminogen, in both the absence and the presence of fibrin. In citrated human plasma in the absence of fibrin, 30 nmol/L STAR did not induce measurable plasminogen activation and PAP formation (< 1.5% within 2 hours), whereas addition of a plasma clot (12% vol) resulted in complete clot lysis and conversion of 19% +/- 8% of the plasminogen to PAP within 2 hours. Addition of a second plasma clot produced 23% +/- 2% additional plasminogen activation. Equipotent concentrations for plasma clot lysis of SK (100 nmol/L) induced 54% +/- 11% plasminogen activation in the absence and 49% +/- 16% in the presence of fibrin. Addition of 50 mmol/L 6-aminohexanoic acid (6-AHA) abolished the effect of fibrin on plasminogen activation with STAR, but not on activation with SK. In alpha 2-antiplasmin-depleted human plasma in the absence of fibrin, 30 nmol/L STAR did not induce fibrinogen breakdown (> 90% residual fibrinogen after 6 hours), whereas 30 nmol/L preformed plasmin-STAR complex induced extensive fibrinogen degradation (70% within 20 minutes). Thus, in the absence of fibrin, alpha 2- antiplasmin inhibits the activation of plasminogen by STAR, by preventing generation of active plasmin-STAR complex. Fibrin stimulates plasminogen activation by STAR via mechanisms involving the lysine- binding sites of plasminogen, probably by facilitating the generation of plasmin-STAR complex and by delaying its inhibition at the clot surface.     

Isolation and characterization of an acquired antithrombin antibody

A 68-year-old man, following mitral valve replacement, presented with a low-grade chronic consumptive coagulopathy. Laboratory analysis showed mild fibrinolysis, minimal effect of coumadin therapy, and a prolonged thrombin time (greater than 150 seconds using bovine IIa). When purified human IIa was used the thrombin time normalized to within 17 seconds of controls, suggesting a possible inhibitor of bovine IIa. An anti-IIa antibody was isolated by protein A-Sepharose (Sigma, St Louis, MO) chromatography followed by affinity chromatography using a bovine IIa-Sepharose column. The effects of this purified anti-IIa antibody on both bovine and human IIa procoagulant and anticoagulant functions were studied. The isolated immunoglobulin G (IgG) was observed to inhibit bovine IIa in all assays tested. This IgG was also able to slightly prolong fibrinogen clotting by human IIa. Using an enzyme-linked immunosorbent assay it was observed that the IgG bound to bovine IIa, bovine II, human IIa, but not to human II. Further, binding was detectable at approximately 50-fold lower concentrations to bovine IIa (1 nmol/L IgG concentration) than to human IIa (50 nmol/L IgG concentration). The effect of the antibody on the reaction between IIa and AT III/heparin was investigated. Human IIa was found to be protected from AT III/heparin neutralization in the presence of this antibody. These results suggest that this patient developed an antibody that strongly binds to and inhibits the bovine IIa in all assays tested. However, the antibody only significantly affects human IIa neutralization by AT III/heparin, and has little effect on the human IIa procoagulant activity. These data suggest that the decreased effect of AT III/heparin on this patient's IIa may have been a contributing factor in his coagulopathy. The exact cause of this antibody development is unclear, but the role of bovine topical thrombin used during cardiac valve replacement surgery is suspect.     

Determination of the levels of unfractionated and low-molecular-weight heparins in plasma: their effect on thrombin-mediated feedback reactions in vivo. Preliminary results after subcutaneous injection.

We define a standard independent unit (SIU) of heparin as that amount that, in plasma containing 1 mumol of ATIII, raises the (pseudo-)first-order breakdown constant of factor Xa by 1 min-1. These units measure all material with a high affinity for ATIII (HAM); only material above the critical chain length of 17 monosaccharide units (above critical chain length material; ACLM) catalyzes the inactivation of thrombin. An SIU of ACLM is therefore analogously defined as the amount that, in plasma containing 1 mumol of ATIII, will raise the (pseudo-)first-order breakdown constant of thrombin by 1 min-1. Of any given heparin preparation one can determine the specific HAM and ACLM activities in terms of SIU/mg. On the basis of the factor Xa and thrombin breakdown constants found in a plasma sample one can then determine the levels of HAM and ACLM. Preliminary experiments were carried out in plasma samples obtained after subcutaneous injection of unfractionated heparin (UFH) and of two types of low-molecular-weight heparin (LMWH). About three times more of UFH activity than of LMWH activity has to be injected to obtain the same levels of ACLM in the plasma. Only with the LMWHs significant amounts of BCLM are found, which rises higher and persists longer than the ACLM. We determined the course of thrombin generation in platelet-rich plasma (PRP) and in platelet-poor plasma (PPP), as well as in the PPP factor Xa generation curve and the course of prothrombin conversion. The observed inhibitions correlated much better with the levels of ACLM than with those of below critical chain length material. The difference between UFH and LMWHs can therefore not be explained in terms of antithrombin and anti-factor-Xa activity. The essential difference between UFH and LMWH appears in the feedback effect of thrombin in PRP, where thrombin generation is both inhibited and retarded by LMWH, while it is only retarded but hardly inhibited by UFH.     

Ratios of anti-factor Xa to antithrombin activities of heparins as determined in recalcified human plasma

Anti-factor Xa and anti-thrombin activities of unfractionated (UF) and low molecular weight (LMW) heparins have been measured in human plasma and with purified human antithrombin III (ATIII) in the absence and presence of 1.5 mM calcium. The anti-factor Xa and anti-thrombin activities were measured directly, by assessing the heparin-dependent pseudo-first order rate constants of inactivation of human factor Xa or thrombin. These activities were studied with the 4th International Standard for UF heparin, the 1st International Standard for LMW heparin, CY216, enoxaparin, CY222, and the synthetic pentasaccharide. In plasma, calcium equally well increased the specific anti-factor Xa catalytic activities as compared to purified ATIII. That is, 1.5 mM calcium stimulated the UF standard heparin-catalysed inactivation of factor Xa 2.1-2.4 times. In the presence of the LMW heparins the effect of calcium was smaller (1.3-1.7 times), and in plasma there was no effect of calcium on the pentasaccharide-catalysed inactivation of factor Xa. Thus, the largest effects of calcium in the inactivation reaction of factor Xa is seen with UF standard heparin. Calcium reduced the anti-thrombin activities of all the heparin preparations studied about 1.5 times when purified ATIII was used, although in plasma this effect was less clear. Consequently, in the presence of 1.5 mM calcium the ratio of the anti-factor Xa to the anti-thrombin activities of UF standard heparin approximated those of the LMW heparins. The only exception was CY222, which under all conditions retained anti-factor Xa/anti-thrombin ratios significantly higher than those of UF standard heparin.     

Heparin-catalyzed inhibitor/protease reactions: kinetic evidence for a common mechanism of action of heparin.

Three different heparin-catalyzed inhibitor/protease reactions were studied: antithrombin III/thrombin, heparin cofactor II/thrombin, antithrombin III/factor Xa. The three reactions were saturable with respect to both inhibitor and protease. The initial reaction velocity, for each reaction, could be described by the general rate equation for a random-order bireactant enzyme-catalyzed reaction. The kinetic parameters for the heparin-catalyzed antithrombin III/thrombin and antithrombin III/factor Xa reactions differed in terms of apparent maximum velocity (Vmax) and apparent heparin-protease dissociation constant values. The apparent heparin-antithrombin III dissociation constant values were the same for both reactions. The kinetic parameters for the heparin-catalyzed antithrombin III/thrombin and heparin cofactor II/thrombin reactions differed in terms of apparent Vmax and apparent heparin-inhibitor dissociation constant values. The apparent heparin-thrombin dissociation constant values were the same for both reactions. The results are consistent with a general mechanism of action of heparin for the three reactions that, in its simplest form, requires only that both protease and inhibitor bind to heparin for catalysis to occur.     

Studies on the mechanism of expression of secreted fibrinogen on the surface of activated human platelets

Affinity purified anti-fibrinogen (anti-Fg) Fab fragments were used to study the mechanism of expression of alpha-granule fibrinogen on activated platelets. Low amounts of the radiolabeled anti-Fg Fab bound to unstimulated or adenosine diphosphate (ADP)-stimulated cells. They readily bound to platelets stimulated with collagen, alpha-thrombin or gamma-thrombin in the presence of divalent cations. At 1 n mol/L alpha- thrombin or 25 nmol/L gamma-thrombin, platelet fibrinogen was expressed on the surface of the cells notwithstanding the presence of AP-2, a monoclonal antibody to the glycoprotein (GP) IIb-IIIa complex, or the synthetic peptides Arg-Gly-Asp-Ser and gamma 400-411, all substances that prevented the binding of plasma fibrinogen to platelets. These results suggest that platelet fibrinogen may interact with its receptors during its translocation from the alpha-granules to the plasma membrane and, thus, not occupy the same sites as those available for plasma fibrinogen on the surface of the cell. Furthermore, we found that platelet fibrinogen was expressed on the thrombin-stimulated platelets of a Glanzmann's thrombasthenia variant that failed to bind plasma fibrinogen. Normal platelets stimulated with 5 nmol/L alpha- thrombin bound increased amounts of the anti-fg Fab, the additional expression being inhibited by the anti-GP IIb-IIIa monoclonal antibody or by Gly-Pro-Arg-Pro, an inhibitor of fibrin polymer formation. This suggests that rebinding to externally located GP IIb-IIIa complexes becomes important once fibrin is formed.     

Low molecular weight heparins prevent thrombin-induced thrombo-embolism in mice despite low anti-thrombin activity. Evidence that the inhibition of feed-back activation of thrombin generation confers safety advantages over direct thrombin inhibition

BACKGROUND AND OBJECTIVES: Thrombin-induced thromboembolism in mice is a model in which the feed-back clotting activation produced by the injected enzyme greatly contributes to fibrin accumulation in lungs and to mortality. Using this model we have previously shown that activated human protein C (aPC), by interrupting endogenous clotting activation at a high level (factors Va and VIIIa), prevents mortality inducing only a minor hemostatic impairment. With the same model we have now compared the antithrombotic and prohemorrhagic effects of two low molecular weight heparins (LMWHs), reviparin and tinzaparin, which are expected to inhibit preferentially the positive feed-back triggered by thrombin (anti Xa activity), with those of unfractionated heparin (UFH) and PEG-hirudin, which inhibit mainly or exclusively thrombin activity (anti IIa activity). DESIGN AND METHODS: Pulmonary thromboembolism was induced in mice by i.v. injection of bovine thrombin (1,000U/kg). Drugs (from 0.12 to 1.2 mg/kg) were given as bolus injection 2 min prior to thrombin challenge and mortality was assessed within 15 min. The bleeding time was assessed by a tail tip transection model. Activated partial thromboplastin time (aPTT), thrombin clotting time (TcT), fibrinogen assay and anti Xa activity determination were performed in citrated plasma from saline- or drug-treated animals. RESULTS: All drugs protected mice from thrombin-induced mortality in a dose-dependent way. At comparable antithrombotic dosages, the anti IIa activity generated in plasma (assessed by TcT) was highest with UFH, intermediate with tinzaparin and very low with reviparin. Accordingly, the fibrinogen drop, which is caused mainly by the injected thrombin, was prevented by the heparins to an extent that was fairly well related to their anti IIa activity. aPTT and bleeding time, used as measures of hemorrhagic risk, were markedly more prolonged by UFH than by reviparin. Tinzaparin, instead, had an intermediate effect. Interestingly, PEG-hirudin, at equipotent antithrombotic dosages, caused a prolongation of bleeding time comparable to that observed with UFH. INTERPRETATIONS AND CONCLUSIONS: Our data show that, in our model, drugs acting at a high level of the blood clotting cascade, like LMWHs with a high anti Xa/anti IIa ratio, display a better antithrombotic/prohemorrhagic profile than drugs acting prevalently on thrombin.     

The effect of fibrin polymers on thrombin-catalyzed plasma factor XIIIa formation

The effect of fibrin polymers on thrombin-catalyzed factor XIIIa formation was studied in afibrinogenemic plasma. Fibrin polymers derived from des A fibrinogen and des A,B fibrinogen increased sixfold the rate of thrombin-catalyzed factor XIIIa formation in the presence of EDTA. Calcium chloride accelerated factor XIIIa formation 14-fold in the presence of des A,B fibrinogen without increasing the rate of thrombin formation. Fibrinopeptides A and B had no effect on factor XIIIa formation in afibrinogenemic plasma. Des A,B fibrinogen reduced by 20- to 40-fold the thrombin concentration required to activate factor XIII. Glycyl-L-prolyl-L-arginyl-L-proline (gly-pro-arg-pro), a fibrin polymerization inhibitor, inhibited des A and des A,B fibrinogen from enhancing thrombin-catalyzed factor XIIIa formation. Gly-pro-arg- pro did not modify factor XIIIa formation in afibrinogenemic plasma and did not inhibit thrombin cleavage of the chromogenic substrate S-2238. These results demonstrate that fibrin polymers accelerate thrombin- catalyzed plasma factor XIIIa formation.     

Comparing techniques: the use of recalcified plasma in comparison with citrated plasma alone and in combination with thrombin in ultrastructural studies

Fibrin plays a vital role in the coagulation process and fibrin fiber morphology can be studied using ultrastructural techniques. When studying the ultrastructure of fibrin networks, thrombin may be added to the plasma, ensuing fibrin network formation. The question that arises is whether there are differences in morphology when thrombin is added to plasma, versus morphology observed when plasma from citrated or recalcified citrated whole blood, is studied. The current study therefore aimed to compare ultrastructure of platelets and fibrin networks from these three techniques. Results indicated comparable platelet ultrastructure between smears formed from the plasma of citrated blood and that of the citrated recalcified blood. This method might give us further information regarding the 'natural state' fibrin assembly and association with platelets, when studying haemostasis. However, when studying the ultrastructure of fibrin networks, the addition of thrombin is necessary to form an expansive, fully coagulated layer of fibrin fibers.     

Heparin cofactor II activity in patients with disseminated intravascular coagulation and hepatic failure

Heparin cofactor II (HCII) is a glycoprotein in human plasma which inactivates thrombin rapidly in the presence of heparin or dermatan sulfate. We have developed a functional assay for HCII in which inhibition of thrombin by plasma is determined in the presence of dermatan sulfate. The assay is specific for HCII by the following criteria: (a) under the conditions of the assay, 125I-thrombin forms complexes in plasma which comigrate with the thrombin-HCII complex during sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS- PAGE); (b) activity detected by the assay is decreased in plasma absorbed with monospecific antibodies against HCII; and (c) purified antithrombin III (ATIII) is unreactive in the assay system. Addition of Polybrene to the assay permits determination of HCII activity in samples containing less than or equal to 12 U/mL of heparin. The range of HCII concentrations in normal individuals is 1.2 +/- 0.4 mumol/L (mean +/- 2 SD, n = 34). HCII activity was determined in 54 consecutive patients undergoing evaluation for the possibility of disseminated intravascular coagulation (DIC). Ten of the 11 patients with documented DIC had decreased HCII activity as compared with only 7 of the 43 patients without DIC (chi 2 = 19.3, P less than .0001). The concentrations of HCII and ATIII varied in parallel in most of the patients tested. A significant correlation between decreased HCII activity and decreased serum albumin concentration was also observed in these patients and in eight additional patients with hepatic failure in the absence of DIC. We conclude that HCII activity is decreased in many patients with DIC and hepatic failure.     

A study of the large heparin requirements in the generalized Shwartzman reaction.

The heparin requirements necessary to inhibit intravascular fibrin deposition and soluble fibrin monomer (FM) formation in the generalized Shwartzman reaction (GSR) were evaluated. Fibrin deposition was measured by a quantitative technique utilizing 125I-labeled rabbit fibrinogen. FM was measured semiquantitatively by gel exclusion chromatography and by the serial dilution protamine sulfate (SDPS) test. There was a fourfold increase in heparin requirement 5 min after compared with 5 min before the second dose of endotoxin. This increase in heparin requirement was not related to thrombin elaboration, since FM was not found until more than 1 hr after the second dose of endotoxin. Neither was there any evidence of diminished sensitivity to the anticoagulant effect of heparin. The heparin requirements in the GSR rabbits were found to be in excess of those needed to neutralize a defibrinating dose of thrombin. It was concluded that a potent, heparin-resistant clotting activity developed within 5 min of the second endotoxin injection. The mechanism by which the activity caused the gradual elaboration of a thrombin-like enzyme is diffucult to explain on the basis of traditional coagulation reactions. The apparent role of white cells is discussed.     

The effect of a low molecular mass thrombin inhibitor, inogatran, and heparin on thrombin generation and fibrin turnover in patients with unstable coronary artery disease.

AIM: This study evaluated a novel specific thrombin inhibitor, inogatran, in comparison with unfractionated heparin, with regard to markers for coagulation activity in patients with unstable coronary artery disease. METHODS AND RESULTS: In the Thrombin Inhibition In Myocardial Ischaemia (TRIM) study patients were randomized to one of three different doses of inogatran or to unfractionated heparin, given intravenously over 72 h. In a subpopulation of 320 patients, markers for coagulation activity were measured at baseline, during and after the study infusion. Prothrombin fragment 1 + 2, indicating thrombin generation, decreased in the low, medium and high dose inogatran groups and in the heparin group during the first 6 h of treatment by 12%, 15%, 21% and 26%, respectively. From 6 h to 72 h after the start of infusion the levels changed by -7%, -6%, -4% and +34%, respectively. The increase in the heparin group continued after the infusion was stopped. Thrombin-antithrombin complex, also indicating thrombin generation, decreased by 0%, 2%, 18% and 22%, respectively, during the first 6 h of treatment. During the same period soluble fibrin, an intermediate in fibrin formation, increased both in the low and medium inogatran group by 9%, while a decrease by 4% and 18%, respectively, was seen in the high dose inogatran group and in the heparin group. Fibrin dissolution, as measured by fibrin D-dimer, decreased during the first 24 h of treatment by 20%, 18%, 18% and 20%, respectively. The first 24 h after discontinuation of infusion, fibrin D-dimer increased by 6%, 23%, 25% and 44%, respectively. After 72 h, at the end of infusion, patients treated with inogatran, to a larger extent than those given heparin, had suffered from death, myocardial infarction or refractory angina pectoris. After 7 days this trend was less marked. CONCLUSION: The more pronounced decrease in thrombin generation and fibrin turnover during the first 6 h of infusion, and the later increase in thrombin generation and fibrin turnover, in the heparin group, as compared to the inogatran groups, may be related to the lower clinical event rate during infusion with heparin compared with inogatran and the recurrence of ischaemic events, early after cessation of heparin infusion.     

Thrombin-activated thrombelastography for evaluation of thrombin interaction with thrombin inhibitors.

For intravenous anticoagulation, heparin has been the mainstay drug, but its use may be contraindicated in heparin-induced thrombocytopenia and thrombosis. Heparin alternatives including direct thrombin inhibitors are available, but clotting assays (e.g. partial thromboplastin time) measure the time required to form fibrin gel when only a small amount of thrombin is generated. It was hypothesized that the extent of thrombin inhibition varies among inhibitors, and thrombin-activated thrombelastography would provide useful data on therapeutic responses to thrombin inhibitors. Thrombin was added (0-100 nmol/l final concentration) to nonrecalcified whole blood to evaluate clot formation on thrombelastography. Effects of direct thrombin inhibitors (argatroban 3.75 microg/ml, bivalirudin 15 microg/ml, and lepirudin 3.0 microg/ml), and heparin cofactor II activator and dermatan disulfate (20 microg/ml) were evaluated in the presence of 100 nmol/l thrombin. The interactions of thrombin and respective inhibitors were also compared by fluorogenic thrombin substrate cleavage. Increasing concentrations of thrombin progressively shortened the lag time and increased viscoelasticity on thrombelastography. Only 20 nmol/l thrombin caused instantaneous clotting, but maximal viscoelastic force was obtained at 50-100 nmol/l thrombin. All thrombin inhibitors prolonged the lag time (lepirudin > bivalirudin > argatroban = dermatan disulfate), but full recovery of thrombelastography viscoelasticity was observed with argatroban and bivalirudin. Lepirudin abrogated clotting, and dermatan disulfate suppressed clot development on thrombelastography. Thrombin substrate cleavage was observed only for bivalirudin, and heparin cofactor II without dermatan disulfate. The modified thrombelastography technique using nonrecalcified whole blood may be useful in evaluating the extent and reversibility of thrombin blockade with direct or indirect thrombin inhibitors.     

Intraperitoneal heparin in peritoneal dialysis and its effect on fibrinopeptide A in plasma and dialysate

In 6 patients on continuous ambulatory peritoneal dialysis we investigated the inhibition of intraperitoneal fibrin formation by heparin. A continuous addition of 500 U of heparin per liter dialysate was used for 52 h. In plasma no heparin activity could be detected, even 52 h after intraperitoneal administration of heparin. The fibrin formation was determined by fibrinopeptide A, a thrombin-induced split product of fibrinogen. In patients under regular continuous ambulatory peritoneal dialysis we determined the fibrinopeptide A concentrations in plasma. The values were comparable with the fibrinopeptide A concentrations measured in disseminated intravascular coagulopathy. They decreased during intraperitoneal administration of heparin from 63.2 +/- 11.8 to 4.9 +/- 1.7 ng/ml. The fibrinopeptide A concentration in the 4-hour intraperitoneal dialysate (155.8 +/- 15.7 ng/ml) decreased after heparin administration to 8.5 +/- 2.0 ng/ml and was always higher than in plasma. We conclude that 500 U heparin per liter dialysate prevents the intraperitoneal fibrin formation. The low antithrombin III concentration (0.44 +/- 0.13 mg/dl) in protein-poor dialysate seems to be sufficient to inhibit the thrombin activity after acceleration by heparin.     

Comparing techniques: the use of recalcified plasma in comparison with citrated plasma alone and in combination with thrombin in ultrastructural studies

Abstract

Fibrin plays a vital role in the coagulation process and fibrin fiber morphology can be studied using ultrastructural techniques. When studying the ultrastructure of fibrin networks, thrombin may be added to the plasma, ensuing fibrin network formation. The question that arises is whether there are differences in morphology when thrombin is added to plasma, versus morphology observed when plasma from citrated or recalcified citrated whole blood, is studied. The current study therefore aimed to compare ultrastructure of platelets and fibrin networks from these three techniques. Results indicated comparable platelet ultrastructure between smears formed from the plasma of citrated blood and that of the citrated recalcified blood. This method might give us further information regarding the ‘natural state’ fibrin assembly and association with platelets, when studying haemostasis. However, when studying the ultrastructure of fibrin networks, the addition of thrombin is necessary to form an expansive, fully coagulated layer of fibrin fibers.