Abstract-This review examines the evidence that platelets play a major role in localizing and controlling the burst of thrombin generation leading to fibrin clot formation. From the first functional description of platelets, it has been recognized that platelets supply factors that support the activation of prothrombin. Studies have demonstrated that on activation, the amount of one specific lipid, phosphatidylserine, is significantly increased on the outer leaflet of platelet membranes. When it was found that phosphatidylserine containing lipid extracts could be substituted for platelets in clotting assays, this suggested the possibility that changes in platelet lipid composition were necessary and sufficient to account for platelet surface thrombin generation. Because a growing body of data suggest that platelet-binding proteins provide much of the specificity for platelet thrombin generation, we review in this report data suggesting that changes in lipid composition are necessary but not sufficient to account for platelet surface regulation of thrombin generation. Also, we review data suggesting that platelets from different individuals differ in their capacity to generate thrombin, whereas platelets from a single subject support thrombin generation in a reproducible manner. Individual differences in platelet thrombin generation might be accounted for by differences in platelet-binding proteins.
High‐dose recombinant factor VIIa has been successfully used as therapy for haemophiliacs with inhibitors. The mechanism by which high‐dose factor VIIa supports haemostasis is the subject of some controversy. Postulating a mechanism in which activity is dependent on tissue factor at the site of injury explains the localization of activity but not the requirement for high doses. Postulating a mechanism in which factor VIIa acts on available lipid independently of tissue factor explains the requirement for high doses but not the lack of systemic procoagulant activity. We report that factor VIIa bound weakly to activated platelets (Kd ∼ 90 nm). This factor VIIa was functionally active and could initiate thrombin generation in the presence of plasma concentrations of prothrombin, factor X, factor V, antithrombin III and tissue factor pathway inhibitor. The activity was not dependent on tissue factor. The concentration of factor VIIa required for detectable thrombin generation agreed well with the lowest concentration of factor VIIa required for efficacy in patients. High‐dose factor VIIa may function on the activated platelets that form the initial haemostatic plug in haemophilic patients. These observations are in agreement with clinical trials which have shown that high‐dose factor VIIa was haemostatically effective without causing systemic activation of coagulation.
Recombinant factor VIIa was initially developed for the treatment of hemorrhagic episodes in hemophilic patients with inhibitors to factors VIII and IX. After its introduction, it has also been used "off-label" to enhance hemostasis in nonhemophilic patients who experience bleeding episodes not responsive to conventional therapy. Evidence so far indicates that the use of factor VIIa in hemophilic patients with inhibitors is both safe and effective. Anecdotal reports also suggest that the product is safe and effective in controlling bleeding in nonhemophilic patients. However, its use in these conditions has not been approved by the FDA, and conclusive evidence of its effectiveness from controlled clinical trials is not yet available. Several questions pertaining to the use of factor VIIa require further investigation, including the mechanism of action; the optimal dose; definitive indications; ultimate safety; and laboratory tests for monitoring therapy. (Blood.
The pharmacokinetics of rFVIIa are linear in the dose range evaluated. The results suggest potential value of prothrombin time determination in the monitoring of rFVIIa therapy.
Recombinant factor VIIa (rFVIIa) was developed to provide an improved procoagulant component capable of 'by-passing' inhibitor antibodies in the treatment of haemophilic patients. The primary objective of this study was to compare the efficacy of two dosage regimens of rFVIIa (given intravenously at periodic intervals) in the treatment of joint, muscle and mucocutaneous haemorrhages in persons with haemophilia A and B with and without inhibitors. The study was designed as a randomized, double-blind, parallel group, international multicenter trial. Patients were randomly allocated to treatment A: 35 mu kg-1 or B: 70 mu kg-1, in blocks of 2. Within each block, one patient was assigned to the 35 mu kg-1 dosing regimen and the other to 70 mu kg-1 dose. One hundred and fifty subjects from 20 sites were screened for this study and 116 had baseline assessments. Of these, 84 were treated on the protocol and 32 were not treated in the study, in most cases because they did not return to the clinic with an eligible bleeding episode. One hundred and seventy-nine bleeding episodes were treated, of which 145 (81%) were acute haemarthroses. Both treatments were efficacious, with 71% having an excellent (59% and 60%) or effective (12% and 11%) response. Overall, the mean and median number of doses given per episode of joint bleeding were 3.1 and 2, respectively. The mean number of doses was 3.1 for the 70 mu kg-1 group and 2.7 for the 35 mu kg-1 group (P value = 0.142). The study concluded that rFVIIa in a dosage of 35 mu kg-1 or 70 mu kg-1 is both safe and reasonably effective in the treatment of joint or muscle haemorrhages in haemophilic patients with inhibitor antibodies to factor VIII or factor IX. It is concluded that the appropriate dose for the treatment of joint and peripheral muscle bleeding in haemophilic patients with inhibitors is 35-70 mu kg-1 given at 2-3 h intervals until haemostasis is achieved.
We have developed a cell-based model of thrombin generation using activated monocytes as a source of tissue factor (TF) and platelets serving as a surface for thrombin generation. Monocytes are activated by lipopolysaccharide and express cell-bound TF. To these are added physiologic (plasma) concentrations of all the plasma procoagulants as well as TF pathway inhibitor, antithrombin, and C1-esterase inhibitor. Coagulation takes place in microtiter wells and is initiated by factor VIIa (FVIIa) and calcium. At time intervals, aliquots are removed, platelet activation is measured by the expression of P-selectin, and thrombin generation is measured by chromogenic assay. In addition, one can measure the activation of FIX, FX, FVIII, FV, and FXI. Initial results reveal that the FVIIa-TF interaction results in the activation of FX to FXa and FIX to FIXa. FXa stays in the vicinity of the TF-bearing cell and, in the presence of FVa, converts a small amount of prothrombin to thrombin on the surface of the TF cell. This small amount of thrombin is not sufficient to clot fibrinogen, but is sufficient to activate platelets and FVIII, FV, and FXI. Following platelet activation, FVIIIa, FVa, and FXa occupy sites on the activated platelet surface. FIXa, activated by TF-FVIIa, does not remain on the TF cell, but converts FX to FXa on the platelet surface. FXIa acts to boost FIXa generation on the activated platelet, increasing FXa and subsequent thrombin generation. We have also shown that activated protein C does not inactivate Va on the platelet surface but rather on endothelial cell surfaces.
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