Samad Barzegar

The activation of factor X and prothrombin by recombinant factor VIIa in vivo is mediated by tissue factor.

The human coagulation system continuously generates very small quantities of Factor Xa and thrombin. Current evidence suggests that basal level activation of the hemostatic mechanism occurs via Factor VIIa-dependent activation of Factor X, but direct proof has not been available for the participation of tissue factor in this pathway. To examine this issue, we infused relatively high concentrations of recombinant Factor VIIa (approximately 50 micrograms/kg body wt) into normal chimpanzees and observed significant increases in the plasma levels of Factor IX activation peptide, Factor X activation peptide, and prothrombin activation fragment F1+2. Metabolic turnover studies with radiolabeled Factor IX activation peptide, Factor X activation peptide, and F1+2 indicate that elevated levels of the activation peptides are due to accelerated conversion of the three coagulation system zymogens into serine proteases. The administration of a potent monoclonal antibody to tissue factor, which immediately neutralizes function of the Factor VIIa-tissue factor complex in vitro, abolishes the activation of Factor X and prothrombin mediated by the infused recombinant protein, and also suppresses basal level activation of Factor IX and Factor X. The above results suggest that recombinant Factor VIIa functions as a prohemostatic agent by interacting with endogenous tissue factor sites, but definitive proof will require studies in hemophilic animals using relevant hemostatic endpoints.

Comparison of Novel Hemostatic Factors and Conventional Risk Factors for Prediction of Coronary Heart Disease

Background—This study sought to assess whether novel markers of hemostatic activity are predictive of coronary heart disease (CHD) and improve risk assessment. Methods and Results—Conventional CHD risk factors, the activation peptides of factor IX and factor X, factor VII activity and antigen, activated factor XII, prothrombin fragment 1+2, fibrinopeptide A, and fibrinogen were measured in 1153 men aged 50 to 61 years who were free of myocardial infarction at recruitment. Activated factor VII (VIIa) was measured in 829 men. During 7.8 years of follow-up, 104 had a CHD event. Baseline status was related to outcome by logistic regression by using a modified nested case-control design. Screening performance was judged from receiver operating characteristic curves. A high activated factor XII was associated with increased CHD risk, but low levels were not protective. Plasma VIIa and factor X activation peptide were independently and inversely related to risk. Plasma factor IX activation peptide and fibrinogen were positively associated with risk, but the relations were no longer statistically significant after adjustment for other factors, including VIIa and apoA-I. Other hemostatic markers were not associated with CHD risk. Conclusions—Hemostatic status did not add significant predictive power to that provided by conventional CHD risk factors yet was able to substitute effectively for these factors.

Normal levels of anticoagulant heparan sulfate are not essential for normal hemostasis

Endothelial cell production of anticoagulant heparan sulfate (HS(act)) is controlled by the Hs3st1 gene, which encodes the rate-limiting enzyme heparan sulfate 3-O-sulfotransferase-1 (3-OST-1). In vitro, HS(act) dramatically enhances the neutralization of coagulation proteases by antithrombin. The in vivo role of HS(act) was evaluated by generating Hs3st1(-/-) knockout mice. Hs3st1(-/-) animals were devoid of 3-OST-1 enzyme activity in plasma and tissue extracts. Nulls showed dramatic reductions in tissue levels of HS(act) but maintained wild-type levels of tissue fibrin accumulation under both normoxic and hypoxic conditions. Given that vascular HS(act) predominantly occurs in the subendothelial matrix, mice were subjected to a carotid artery injury assay in which ferric chloride administration induces de-endothelialization and occlusive thrombosis. Hs3st1(-/-) and Hs3st1(+/+) mice yielded indistinguishable occlusion times and comparable levels of thrombin.antithrombin complexes. Thus, Hs3st1(-/-) mice did not show an obvious procoagulant phenotype. Instead, Hs3st1(-/-) mice exhibited genetic background-specific lethality and intrauterine growth retardation, without evidence of a gross coagulopathy. Our results demonstrate that the 3-OST-1 enzyme produces the majority of tissue HS(act). Surprisingly, this bulk of HS(act) is not essential for normal hemostasis in mice. Instead, 3-OST-1-deficient mice exhibited unanticipated phenotypes suggesting that HS(act) or additional 3-OST-1-derived structures may serve alternate biologic roles.

Suppression of hemostatic system activation by oral anticoagulants in the blood of patients with thrombotic diatheses.

RIAs for hemostatic system activation were employed to study patients who were anticoagulated with warfarin. The mean prothrombin fragment F1 + 2 concentration in stably anticoagulated individuals without an inherited thrombotic diathesis (mean prothrombin time [PT] ratio [PT of patient/PT of normal plasma pool] = 1.74) was 0.231 nM as compared with a mean plasma F1 + 2 level of 1.68 nM for a nonanticoagulated control group (P less than 0.0001). The initiation of oral anticoagulants in two subjects who did not exhibit protein C deficiency led to a paradoxical increase in F1 + 2 levels during the first day of therapy. We have also shown that a relatively low intensity regimen of warfarin (PT ratio less than 1.2) may reduce elevated concentrations of F1 + 2 into the normal range in patients with a history of recurrent thromboembolism. The mean F1 + 2 level in antithrombin-deficient individuals on warfarin was significantly elevated (mean = 0.714 nM) as compared with that in anticoagulated subjects with protein C deficiency (mean = 0.205 nM) or in those without an inherited thrombotic disorder (P less than 0.01) at equivalent levels of intensity of oral anticoagulation. We therefore conclude that the effect of warfarin on hemostatic system activation is modulated by the endogenous heparan sulfate-antithrombin mechanism.

Activation of Clotting Factors XI and IX in Patients With Acute Myocardial Infarction

In acute coronary events, plaque rupture and the subsequent formation of the catalytic tissue factor–factor VIIa complex is considered to initiate coagulation. It is unknown whether clotting factors XI and IX are activated in acute coronary events. Therefore, we prospectively investigated the activation of clotting factors XI and IX as well as activation of the contact system and the common pathway in 50 patients with acute myocardial infarction (AMI), in 50 patients with unstable angina pectoris (UAP), and in 50 patients with stable angina pectoris (SAP). Factor XIa–C1 inhibitor complexes, which reflect acute activation of factor XI, were detected in 24% of the patients with AMI, 8% of the patients with UAP, and 4% of the patients with SAP (P <0.05), whereas factor XIa–&agr;1-antitrypsin complexes, which reflect chronic activation, were observed equally in all 3 study groups. Factor IX peptide levels were significantly higher in the patients with AMI and UAP compared with the patients with SAP (P <0.01). No differences regarding markers of the common pathway were demonstrated. Fibrinopeptide A levels were elevated in patients with AMI compared with patients with UAP and those with SAP (P <0.01). Factor XIIa– or kallikrein–C1 inhibitor complexes were not increased. In conclusion, this is the first demonstration of the activation of clotting factors XI and IX in patients with acute coronary syndromes. Because these clotting factors are considered to be important for continuous thrombin generation and clot stability, their activation might have clinical and therapeutic consequences.

No activation of the common pathway of the coagulation cascade after a highly purified factor IX concentrate

Purer factor IX concentrates, containing very little or no factor II or X, have been developed in an attempt to avoid the thromboembolic complications that occur with prothrombin complex concentrates (PCC), which also contain factors II and X and variable amounts of factor VII. To evaluate ex vivo the thrombogenic potential of one of these purer concentrates, we studied whether large single doses produced signs of activation of the coagulation cascade in patients with haemophilia B, and compared the results with those obtained after infusion of a PCC. Seven patients were infused with 50 IU/kg of factor IX concentrate and seven additional patients were subsequently infused with 100 IU/kg of the same concentrate. After the infusions, factor IX levels rose in proportion to the administered dose while the concentrations of factor II and factor X did not rise at all. At both doses of concentrate, we did not observe significant postinfusion increments in the levels of the factor X activation peptide (a measure of the activity of the factor VIla‐tissue factor complex and/or the factor IXa‐VIIIa‐activated surface complex), prothrombin fragment 1 + 2 (a measure of factor Xa activity), and fibrinopeptide A (a measure of thrombin activity). We also infused 10 patients with a PCC (50 IU/kg). After the infusions, significant rises in the concentrations of the factor X activation peptide and prothrombin fragment were observed. Therefore, it appears that the infusion of a PCC to patients with haemophilia B can augment factor X activation and subsequently thrombin generation in vivo and that this process can be abrogated by the administration of more pure factor IX concentrate.

Influence of anticoagulants used for blood collection on plasma prothrombin fragment F1+2 measurements

The levels of prothrombin fragment F1 + 2 were measured by a double antibody radioimmunoassay in blood samples collected into different anticoagulant solutions. We evaluated healthy males between the ages of 42 and 77, asymptomatic patients with hereditary deficiencies of protein C or protein S, and persons receiving tumor necrosis factor infusions. The results in specimens collected in an anticoagulant containing ACD, EDTA, adenosine, and 25 U/ml of heparin (a) were highly correlated with those collected in an anticoagulant containing a synthetic thrombin inhibitor, EDTA, and aprotinin (b). However, in asymptomatic patients with congenital antithrombin III deficiency, we found that the plasma levels of F1 + 2 in blood collected in anticoagulant (a) were usually substantially higher than those collected in anticoagulant (b). We determined that this phenomenon was not attributable to the venipuncture procedure itself, but rather appears to be due to the action of low concentrations of heparin in the presence of reduced blood levels of antithrombin III. Our data show that the previously documented elevations in plasma F1 + 2 levels in patients with congenital antithrombin III deficiency appear to be caused by the above in vitro anticoagulant effect, and that this population does not exhibit evidence of a prethrombotic state as defined by the F1 + 2 assay.

Thrombin generation in non-cardioembolic stroke subtypes The Hemostatic System Activation Study

Background: The association between hemostatic activation, stroke mechanism, and outcome is poorly defined. The Hemostatic System Activation Study (HAS) investigators measured serial levels of prothrombin fragment F1.2, a marker of thrombin generation, in patients enrolled in the Warfarin Aspirin Recurrent Stroke Study (WARSS). Methods: HAS enrolled 631 of the 2,206 patients in WARSS. Strokes were subtyped according to inferred mechanism. Plasma was collected for F1.2 at randomization (within 30 days of stroke), 3 months, 12 months, and 18 months. The 3 to 6 month samples in aspirin-treated patients were used for the primary analysis. Results: The authors analyzed 3 to 6 month samples on 320 patients. Higher F1.2 levels were associated with older age, female sex, and hypertension. There was no difference between mean F1.2 levels in 56 cryptogenic (0.9 ± 0.32 nmol/L) and 114 non-cryptogenic (1.13 ± 0.74 nmol/L) patients or across specific stroke subtypes. There was an 8.8%/year (p = 0.006) increase in mean F1.2 levels. There was a trend toward higher risk of recurrent stroke or death as F1.2 levels increased in aspirin (RR: 1.30, 95% CI: 0.57 to 2.94, p = 0.53) and warfarin treated patients (RR: 1.68, 95% CI: 0.48 to 5.94, p = 0.42). F1.2 levels were reduced on average 70% in warfarin-treated patients in a dose-dependent fashion. Conclusion: F1.2 levels did not appear to differ by stroke subtype, suggesting that factors other than underlying stroke pathophysiology influence thrombin generation in the post-acute stroke period. F1.2 levels were suppressed by warfarin in a dose-dependent fashion. Additional research is needed to determine the predictive value of F1.2 after stroke.