Recombinant human prothrombin (MEDI8111) prevents bleeding in haemophilia A and B mice.

BACKGROUND: Haemophilia A and B are treated with FVIII and FIX replacement therapy. Treatment may be complicated by inhibitory antibodies that require bypass therapy such as FEIBA(®) in which prothrombin (FII) is suggested to be the main active component. METHODS: To evaluate the effect of FII on haemophilia recombinant human (rh) FII (MEDI8111) or plasma-derived human FII (pdhFII) was given as single doses to anaesthetized haemophilia A and B mice 3 min before tail transection and rhFVIII or rhFIX was used for comparison. After tail transection, automatic bleeding registration was used to continuously measure blood loss (BL) and bleeding time (BT). Thrombin generation and plasma concentrations of human FVIII, FIX, FII and thrombin-antithrombin complex (TAT) were measured. RESULTS: Blood loss and BT were dose-dependently decreased by rhFVIII or rhFIX. The concentrations that decreased BL and BT for rhFVIII by 50% (EC50) were 0.06 and 0.01 IU mL(-1) and for rhFIX 0.07 and 0.07 IU mL(-1) , respectively. Administration of rhFVIII and rhFIX dose-dependently increased thrombin generation potential but did not affect TAT. MEDI8111 and pdhFII dose-dependently decreased BL and BT in haemophilia A mice, EC50 37 and 87 and 100 and 155 mg L(-1) respectively. In haemophilia B mice given MEDI8111 EC50 was for BL 56 mg L(-1) and for BT 67 mg L(-1) . TAT and thrombin generation increased dose-dependently for MEDI8111 and pdhFII. CONCLUSION: MEDI8111 dose-dependently decreased bleeding and increased procoagulant activity in haemophilia A and B mice and suggest that MEDI8111 may be useful for preventing bleeding in patients with haemophilia A and B.

Effects of recombinant human prothrombin on thrombin generation in plasma from patients with hemophilia A and B.

BACKGROUND: The present study was carried out to investigate the impact of FII levels, and their increase, on the hemostatic potential in plasma from hemophilia A and B patients with and without inhibitors. METHOD: Recombinant human factor (F) II (rhFII) was added ex vivo to plasma from 68 patients with hemophilia A and B, with or without inhibitors. The hemostatic potential as measured by thrombin generation (calibrated automated thrombogram [CAT]) was focused on the endogenous thrombin potential (ETP) as it has been shown to correlate with the clinical phenotype of bleeding in hemophilia patients and has also been used to guide bypassing therapy in hemophilia patients with inhibitors before elective surgery. The factor eight inhibitor bypassing agent (FEIBA(®) ) was used as a reference to the clinical situation. RESULTS: The study shows that rhFII concentration-dependently increased ETP by a similar magnitude in hemophilia A and B, both with and without inhibitors. Compared with FEIBA, rhFII showed a shallower concentration-response curve. In both types of hemophilia 100 mg L(-1) of rhFII roughly doubled the ETP. A corresponding response was obtained by 0.5 U mL(-1) of FEIBA. CONCLUSION: These data support the theory that FII is one of the major components responsible for the efficacy of FEIBA. The data also indicate that rhFII may be useful, alone or in combination with other coagulation factors, in some of the conditions for which FEIBA is used today, although more data are needed to substantiate this.

The effect of recombinant and plasma-derived prothrombin on prothrombin time in human plasma.

INTRODUCTION: When investigating coagulation assays to measure the effect of infused prothrombin (FII) in in vivo coagulopathy models, we found that addition of FII, plasma-derived human FII (pd-hFII) or recombinant human FII (r-hFII), to normal plasma resulted in a concentration-dependent increase in prothrombin time (PT) initiated with Innovin(®) . METHODS: The effect on PT by addition to plasma of either pd-hFII or r-hFII, using different commercial PT reagents, was studied both by turbidimetry and viscometry. RESULT: Addition of FII to plasma resulted in increased PT when initiated with Innovin(®) : PT increased with 20% by doubling the concentration. The prolongation of PT became more pronounced with 2-6000 times diluted Innovin(®) . However, by adjustment of the final free Ca(2+) concentration in the assay with diluted Innovin(®) from 8.3 to 1.3 mmol/L, no FII-dependent increase in PT was found. In contrast, no prolongation of PT was found with other commercial PT reagents. A KM = 3 nmol/L was obtained with pd-hFII, respectively, r-hFII with FII-depleted plasma using Thromborel(®) to initiate PT. CONCLUSION: At normal plasma concentration of FII, addition of FII should not have an effect on PT. The prolonged PT with Innovin(®) , but not with other PT reagents, at supranormal FII concentration is an artefact.

The effect of corn trypsin inhibitor and inhibiting antibodies for FXIa and FXIIa on coagulation of plasma and whole blood.

BACKGROUND: Corn trypsin inhibitor (CTI), an inhibitor of FXIIa, is used to prevent plasma coagulation by contact activation, to specifically investigate tissue factor (TF)-initiated coagulation. OBJECTIVE: In the present work the specificity of CTI for factor (F) XIIa is questioned. METHODS AND RESULTS: In the commercial available plasma coagulation assays CTI was found to double activated partial thromboplastin time (APTT) at a plasma concentration of 7.3 ± 1.5 µm CTI (assay concentration 2.4 µm). No effect was found on the prothrombin time (PT) when high TF concentrations were used. Also, with specific antibodies for FXIIa and for FXIa only APTT was found to be extended but not PT. With specific enzyme assays using chromogenic substrates CTI was shown to be a strong inhibitor of FXIIa and a competitive inhibitor of FXIa with Ki  = 8.1 ± 0.3 µm, without effect on the coagulation factors FVIIa, FIXa, FXa and thrombin. In thrombin generation and coagulation (free oscillation rheometry, FOR) assays, initiated with low TF concentrations, no effect of CTI (plasma concentrations of 4.4 and 13.6 µm CTI, 25 resp. 100 mg L(-1) in blood) was found with ≥ 1 pm TF. At ≤ 0.1 pm TF in the FOR whole blood assay the coagulation time (CT) concentration dependently increased while the plasma CT became longer than the observation time. CONCLUSION: To avoid inhibition of FXIa and the thrombin feedback loop we recommend that for coagulation assays the concentration of CTI in blood should be below 20 mg L(-1) (1.6 µm) and in plasma below 3 µm.

Blood plasma coagulation studied by surface plasmon resonance.

A surface plasmon resonance (SPR) apparatus was used to investigate blood plasma coagulation in real time as a function of thromboplastin and heparin concentrations. The response curves were analyzed by curve fitting to a sigmoid curve equation, followed by extraction of the time constant. Clotting activation by thromboplastin resulted in increased time constant, as compared to spontaneously clotted plasma, in a dose dependent way. Addition of heparin to the thromboplastin-activated plasma counteracted this effect. Atomic force microscopy (AFM) pictures of sensor surfaces dried after completed clotting, revealed differences in fibrin network structures as a function of thromboplastin concentration, and the fiber thickness increased with decreased thromboplastin concentration. The physical reason for the SPR signal observed is ambiguous and is therefore discussed. However, the results summarized in the plots and the fibrin network properties observed by AFM correlate well with present common methods used to analyze blood coagulation.

Comparison of surface plasmon resonance and quartz crystal microbalance in the study of whole blood and plasma coagulation.

The coagulation of blood plasma and whole blood was studied with a surface plasmon resonance (SPR) based device and a quartz crystal microbalance instrument with energy dissipation detection (QCM-D). The SPR and QCM-D response signals were similar in shape but differing in time scales, reflecting differences in detection mechanisms. The QCM-D response time was longer than SPR, as a physical coupling of the sample to the substrate is required for molecules to be detected by the QCM-method. Change of sample properties within the evanescent field is sufficient for detection with SPR. Both the SPR signals and the QCM-D frequency and dissipation shifts showed dependency on concentrations of coagulation activator and sensitivity to heparin additions. The ratio of dissipation to frequency shifts, commonly considered to reflect viscoelastic properties of the sample, varied with the concentration of activator in blood plasma but not in whole blood. Additions of heparin to the thromboplastin activated whole blood sample, however, made the ratio variation reoccur. Implications of these observations for the understanding of the blood coagulation processes as well as the potential of the two methods in the clinic and in research are discussed.

Isocitrate as calcium ion activity buffer in coagulation assays.

BACKGROUND: Ca(2+) activity close to the physiological concentration of 1.3 mmol/L is essential in blood coagulation. Is this also true for the performance of global diagnostic coagulation assays? We searched for compounds that would buffer Ca(2+) activity at approximately 1.3 mmol/L without disturbing coagulation reactions and investigated whether such Ca(2+) buffering improves diagnostic efficacy in global diagnostic coagulation tests. METHODS: Buffering was investigated by mixing CaCl(2) and 11 candidate compounds and determining Ca(2+) activity. The best candidates were added to mixtures of plasma and thromboplastin to detect interference with coagulation reactions. The best of these candidates, isocitrate, was used to modify an activated partial thromboplastin time (APTT), buffering final Ca(2+) activity to approximately 1.3 mmol/L. Plasma samples from 22 healthy individuals and 120 patients were analyzed with original and modified APTT to determine whether diagnostic efficacy was improved. RESULTS: Two suitable Ca(2+) buffers, citrate and isocitrate, were found. Isocitrate was preferred as being less coagulation inhibitory, a better Ca(2+) buffer, and possibly a better anticoagulant. The isocitrate-modified APTT showed a final Ca(2+) activity of 1.60 +/- 0.07 mmol/L, compared with 2.73 +/- 0.20 mmol/L for the original APTT. The means and SDs for the healthy individuals were determined for both procedures, and the values were used to express patient deviation from normality (difference from mean divided by SD). The deviation was greater for the modified APTT; 4.3 +/- 5.7, compared with 3.6 +/- 5.0 (P <0.005) for the original APTT. CONCLUSIONS: Isocitrate can be used to buffer Ca(2+) activity at physiological concentrations and can serve as an anticoagulant. APTT with isocitrate-buffered Ca(2+) activity shows signs of improved diagnostic efficacy.

Surface plasmon resonance (SPR) analysis of coagulation in whole blood with application in prothrombin time assay.

It is previously shown that surface plasmon resonance (SPR) can be used to study blood plasma coagulation. This work explores the use of this technique for the analysis of tissue factor induced coagulation, i.e. prothrombin time (PT) analysis, of whole blood and plasma. The reference method was nephelometry. The prothrombin time analysis by SPR was performed by mixing two volumes of blood/plasma, one volume of thromboplastin, and one volume of CaCl2 solution directly on a sensor surface. The measurements show good agreement between nephelometry and SPR plasma analysis and also between SPR plasma and whole blood analysis. The effect of anticoagulant treatment on the clotting times was significant both quantitatively and qualitatively. The impact on the SPR signal of different physiological events in the coagulation process is discussed, and tentative interpretations of the sensorgram features are given. The major advantage of the SPR method compared to nephelometry is the possibility to perform analysis on whole blood instead of plasma. In conclusion, SPR is a promising method for whole blood coagulation analysis.