Simulations of thrombin formation based on plasma composition can discriminate between acute and stable CAD.
The presence of activation peptides (AP) of the vitamin K-dependent proteins in the phlebotomy blood of human subjects suggests that active serine proteases may circulate in blood as well. The goal of the current study was to evaluate the influence of trace amounts of key coagulation proteases on tissue factor-independent thrombin generation using three models of coagulation. With procoagulants and select coagulation inhibitors at mean physiological concentrations, concentrations of factor IXa, factor Xa, and thrombin were set either equal to those of their AP or to values that would result based upon the rates of AP/enzyme generation and steady state enzyme inhibition. In the latter case, numerical simulation predicts that sufficient thrombin to produce a solid clot would be generated in ϳ2 min. Empirical data from the synthetic plasma suggest clotting times of 3-5 min, which are similar to that observed in contact pathway-inhibited whole blood (4.3 min) initiated with the same concentrations of factors IXa and Xa and thrombin. Numerical simulations performed with the concentrations of two of the enzymes held constant and one varied suggest that the presence of any pair of enzymes is sufficient to yield rapid clot formation. Modeling of states (numerical simulation and whole blood) where only one circulating protease is present at steady state concentration shows significant thrombin generation only for factor IXa. The addition of factor Xa and thrombin has little effect (if any) on thrombin generation induced by factor IXa alone. These data indicate that 1) concentrations of active coagulation enzymes circulating in vivo are significantly lower than can be predicted from the concentrations of their AP, and 2) expected trace amounts of factor IXa can trigger thrombin generation in the absence of tissue factor.
It has been established that inflammation and enhanced pro-coagulant activity are associated with the pathogenesis of atherosclerotic vascular disease. We evaluated and compared the contributions of the factor (F)XIa and tissue factor (TF) activity in plasma of patients with coronary artery disease (CAD). Citrate plasma was obtained prior to therapy from 53 patients with stable angina (29 with a history of previous myocardial infarction; CAD-MI) and 30 with acute coronary syndrome (ACS) within 12 hours from pain onset. Four ACS patients treated with heparin were excluded. FXIa and TF activity were determined in clotting assays based upon the prolongation of clotting time by inhibitory monoclonal antibodies. Twenty-five of 26ACS patients (96%) and 22 of 29 CAD-MI patients (76%) had quantifiable FXIa (50 +/- 33 and 42 +/- 45pM, respectively). Ten of 26 (38%) ACS patients and only three of 53 (6%) stable CAD patients showed TF activity (<0.4pM). No FXIa or TF activity was observed in age-matched healthy controls (n = 12). For both CAD-MI and ACS patients, there were correlations (p < 0.05) between FXIa and interleukin-6 (R(2) = 0.59 and 0.39, respectively) and between FXIa and TAT (R(2) = 0.64 and 0.63, respectively). In conclusion, the majority of ACS and CAD-MI patients have circulating FXIa that correlates with markers of coagulation and inflammation.
Summary. Background: Therapeutic agents that regulate blood coagulation are critical to the management of thrombotic disorders, with the selective targeting of factor (F) Xa emerging as a promising approach. Objective: To assess anticoagulant strategies targeting FXa. Methods: A deterministic computational model of tissue factor (Tf)-initiated thrombin generation and two empirical experimental systems (a synthetic coagulation proteome reconstruction using purified proteins and a whole blood model) were used to evaluate clinically relevant examples of the two available types of FXa-directed anticoagulants [an antithrombin (AT)-dependent agent, fondaparinux, and an AT-independent inhibitor, Rivaroxaban] in experimental regimens relevant to long-term (suppression of new Tfinitiated events) and acute (suppression of ongoing coagulation processes) clinical applications. Results: Computational representations of each anticoagulantÕs efficacy in suppressing thrombin generation over a range of anticoagulant concentrations in both anticoagulation regimens were validated by results from corresponding empirical reconstructions and were consistent with those recommended for long-term and acute clinical applications, respectively. All three model systems suggested that Rivaroxaban would prove more effective in the suppression of an ongoing coagulation process than fondaparinux, reflecting its much higher reactivity toward the prothrombinase complex. Conclusion: The success of fondaparinux in acute settings in vivo is not explained solely by its properties as an FXa inhibitor. We have reported that FIXa contributes to the longterm capacity of clot-associated catalysts to restart a coagulation process, suggesting that the enhanced anti-FIXa activity of fondaparinux-AT may be critical to its success in acute settings in vivo.
The function of tissue factor (Tf)-initiated coagulation is hemorrhage control through the formation and maintenance of an impermeable platelet-fibrin barrier. The catalytic processes involved in the clot maintenance function are not well defined, although the rebleeding problems characteristic of individuals with hemophilias A and B suggest a link between specific defects in the Tf-initiated process and defects in the maintenance function. We have previously demonstrated, using a methodology of "flow replacement" (or resupply) of ongoing Tf-initiated reactions with fresh reactants, that procoagulant complexes are produced during Tf-initiated coagulation, which are capable of reinitiating coagulation without input from extrinsic factor Xase activity (Orfeo, T., Butenas, S., Brummel-Ziedins, K. E., and Mann, K. G. The extrinsic or tissue factor (Tf) 2 -initiated pathway is generally considered the essential pathway of hemorrhage control in vivo. In closed model systems used to study blood coagulation, this pathway is characterized by the successive emergence and overlapping expression of three procoagulant complexes. The first complex forms when pre-existent factor (f) VIIa binds to the membrane-bound protein Tf, forming the extrinsic fXase complex (Tf-fVIIa-Ca 2ϩ -membrane). Formation of the extrinsic fXase yields an ϳ10 7 -fold increase in enzymatic activity of fVIIa toward its substrates, fIX and fX (1). fXa produced by the extrinsic fXase directly activates amounts of prothrombin (fII) to thrombin (2) sufficient to activate a fraction of the pro-cofactor pools of fV and fVIII and to begin both the activation of platelets and the conversion of fibrinogen to fibrin (3). These events establish the reaction conditions necessary for the emergence of the two catalytic complexes required for the amplified rates of thrombin formation that characterize an effective hemostatic response: the intrinsic fXase complex (fVIIIa-fIXaCa 2ϩ -membrane), a catalyst that is ϳ50 times more efficient in converting fX to fXa than the extrinsic fXase (4, 5); and the prothrombinase complex (fVa-fXa-Ca 2ϩ -membrane), a catalyst of fII activation that is ϳ10 5 -fold more efficient than fXa (6). Over the course of the reaction, the intrinsic fXase produces the vast majority of the fXa found in the prothrombinase complex (7), whereas thrombin generated by the prothrombinase complex drives most of the platelet activation and fibrin formation. The interplay between the extrinsic and intrinsic fXase functions is highlighted in hemophilias A (fVIII deficiency) and B (fIX deficiency), life-threatening hemorrhagic disorders in which fXa generation, and thus ultimately prothrombinase levels, depend on the less efficient extrinsic fXase complex. Consequences of this reliance on the extrinsic fXase observed using in vitro models of hemophilia include impaired rates and maximum levels of thrombin formation (8 -10), lower levels of prothrombinase (8), altered patterns of fibrin formation (10), and clot architecture (11). These results indicate that t...
Summary. Background: In the extrinsic pathway, the essential procofactors factor (F) V and FVIII are activated to FVa and FVIIIa by thrombin. In the contact pathway and its clinical diagnostic test, the activated partial thromboplastin time (APTT) assay, the sources of procofactor activation are unknown. In the APTT assay, FXII is activated on a negatively charged surface and proceeds to activate FXI, which activates FIX upon the addition of Ca 2+. FIXa feeds thrombin generation through activation of FX. FIXa is an extremely poor catalyst in the absence of its FVIIIa cofactor, which, in the intrinsic FXase complex, increases FXa generation by 10 7 . One potential APTT procofactor activator in this setting is FXIa. Objective: To test the hypothesis that FXIa can activate FVIII and FV. Methods: Recombinant FVIII and plasma FV were treated with FXIa, and the activities and integrities of each procofactor were measured using commercial clotting assays and sodium dodecylsulfate polyacrylamide gel electrophoresis (SDS-PAGE). Results: Kinetic analyses of FXIa-catalyzed activation and inactivation of FV and FVIII are reported, and the the timing and sites of cleavage are defined. Conclusions: FXIa activates both procofactors at plasma protein concentrations, and computational modeling suggests that procofactor activation during the preincubation phase of the APTT assay is critical to the performance of the assay. As the APTT assay is the primary tool for the diagnosis and management of hemophilias A and B, as well as in the determination of FVIII inhibitors, these findings have potential implications in the clinical setting.
Introduction Hemophilia A displays phenotypic heterogeneity with respect to clinical severity. Aim To determine if tissue factor (TF)-initiated thrombin generation profiles in whole blood in the presence of corn trypsin inhibitor (CTI) are predictive of bleeding risk in hemophilia A. Methods We studied factor(F) VIII deficient individuals (11 mild, 4 moderate and 12 severe) with a well-characterized five-year bleeding history that included hemarthrosis, soft tissue hematoma and annual FVIII concentrate usage. This clinical information was used to generate a bleeding score. The bleeding scores (range 0–32) were separated into three groups (bleeding score groupings: 0, 0 and ≤9.6, >9.6), with the higher bleeding tendency having a higher score. Whole blood collected by phlebotomy and contact pathway suppressed by 100μg/mL CTI was stimulated to react by the addition of 5pM TF. Reactions were quenched at 20min by inhibitors. Thrombin generation, determined by ELISA for thrombin – antithrombin was evaluated in terms of clot time (CT), maximum level (MaxL) and maximum rate (MaxR) and compared to the bleeding score. Results Data are shown as the mean±SD. MaxL was significantly different (p<0.001) between the groups: 504±114nM, 315±117nM, and 194±91nM; with higher thrombin concentrations in the groups with lower bleeding scores. MaxR was higher in the groups with a lower bleeding score; 97±51nM/min, 86±60nM/min and 39±16nM/min (p=0.09). No significant difference was detected in CT among the groups, 5.6±1.3min, 4.7±0.7min, 5.6±1.3min. Conclusions Our empirical study in CTI-inhibited whole blood shows that the MaxL of thrombin generation appears to correlate with the bleeding phenotype of hemophilia A.
Factor (F)VII deficiency is an autosomal recessive disorder for which a replacement therapy is not universally available; recombinant FVIIa has been utilized as a therapeutic substitute. As FVII competes with FVIIa for binding to tissue factor in initiating the extrinsic pathway of blood coagulation, a lower dose of FVIIa replacement in cross-reacting material-negative (CRM-) individuals can achieve hemostasis. Three coagulation models (computational, synthetic and in vitro whole blood) were used to predict the FVIIa levels needed to provide apparent hemostasis in a non-bleeding state. Our whole blood results show that a 'normalized' coagulation profile for FVII-deficient individuals has an initiation phase that ends at 5.8 +/- 0.5 min (clot time) and the propagation phase of thrombin generation (thrombin-antithrombin III) yields a maximum concentration of 380 +/- 29 nmol L(-1). When CRM- FVII-deficient subjects were infused with a prophylactic dose of 23 micro g kg(-1) of recombinant FVIIa, 6-8 h postinfusion resulted in a comparable normalized whole blood profile. This FVIIa concentration (0.3-0.7 nmol L(-1)/equivalent dose: 0.8-1.8 micro g kg(-1)) is approximately 1/10 that currently used in treating FVII-deficient individuals and suggests that therapies should be altered relative to the concentration of the FVII zymogen.
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