Study of a therapeutic concentrate of factor VIII/vWf prepared in a closed system

An original procedure of preparation in a closed system of high purity Factor VIII concentrate is presented. Starting from cryoprecipitates, this method involves a first step of partial removal of fibrinogen by glycine precipitation (1.6 M) and a second step of Factor VIII concentration by cryoprecipitation. The yield is 16.5% of plasmatic F VIII:C (0.8 mu/ml.). Several batches of concentrates thus prepared are compared "in vitro" to 9 other commercially available concentrates from 8 different manufactories. The results show that most of the characteristics of our concentrate are within the range of specifications of other commercially available high-purity F VIII concentrate: F VIII: C activity (CRTS Lille concentrate: 25-40 U/ml.; other concentrates: 25-50 U/ml) solubility, specific activity (CRTS lille concentrate; 1.0-1.82 U F VIII:C/mg protein and 1.79-4.8 U F VIII: C/mg clottable proteins; other concentrates: 0.53-2.79 U F VIII:C/mg protein an 1.39-4.84 U F VIII:C/mg clottable proteins), isoagglutinin titers (CRTS Lille concentrate: 2-8 anti-A, 0.16 anti-B; other concentrates: 0-64 anti-A, 8-16 anti-B) F VIIIC/F VIII R: Ag ratios (CRTS Lille concentrate: 0.18-0.49; other concentrates: 0.20-0.42). Furthermore F VIII R:Ag electrophoretic mobility studied by crossed immunoelectrophoresis add F VIII R: RCo assays provide evidence that very high molecular weight multimeric forms of F VIII/vWf which support vWf activity are present in our concentrate. "In vivo" study and clinical efficacy in vWd patients confirm these results and show that our concentrate is appropriate for the treatment of patients with F VIII:C or V VIII R:RCo deficiency.     

Standardization of factor VIII: establishment and use of secondary standards

Two secondary standards for use in routine assays of Factor VIII in therapeutic concentrates and in patients, plasmas, respectively, have been established in a multicenter collaborative study. In order to assess the effect of the adoption of these preparations as common Secondary Standards a comparative assay has been performed: one sample of a Factor VIII concentrate of intermediate purity and one plasma sample have been tested in two laboratories for Factor VIII:C activity using as reference, among others, the common working standard. Analysis of the results shows that with the plasma sample the differences of the estimates obtained with any of the references in our two laboratories were not statistically significant (P greater than 0.3), while with the concentrate sample the differences were always statistically significant (P less than 0.005). The study shows that the adoption of common working standards (besides the uniformity in assay method, reagents and basic equipment) is not sufficient to eliminate interlaboratory variation in the measurement of Factor VIII:C.     

Double cryoprecipitated factor VIII concentrate from heparinised plasma and its heat treatment

In an attempt to implement the small pool concept in Factor VIII purification, cryoprecipitate derived from heparinised plasma was reprecipitated in the cold providing a factor VIII concentrate for freeze drying and heat treatment. There was considerable purification; only 1% of the original plasma proteins was left in the final product. Factor VIII:C concentration was about 19 IU/ml. Factor VIII related antigen (RAg) appeared heterogeneous, with a broad base and asymmetry on crossed immunoelectrophoresis. Fibrinogen content was 15 g/l. In contrast to high-purity commercial concentrates, fibronectin was considerably concentrated. Immunoglobulin contents were similar to a high-purity commercial product. The amount of other plasma proteins was very small, varying from less than 0.2% for C3 complement to 2.3% ceruloplasmin. In some respects the preparation may be considered as an intermediate-purity Factor VIII concentrate. Following addition of 2% sucrose before freeze drying, Factor VIII, total protein and fibrinogen remain virtually stable (less than 15% loss) during heating of the material to 60, 64 or 68 degrees C for 24 to 72 h without changes of protein spectrum following heating. The heated product when stored at 4 degrees C remains stable for at least 3 months. In two severe haemophiliacs receiving this heat treated product, in vivo Factor VIII recovery was 100% with a mean half life of 10.2 h.     

Proteolytic processing of human factor VIII. Correlation of specific cleavages by thrombin, factor Xa, and activated protein C with activation and inactivation of factor VIII coagulant activity

Human factor VIII was isolated from commercial factor VIII concentrates and found to consist of multiple polypeptides with molecular weights ranging from 80 000 to 210 000. Immunological and amino acid sequence data identified these polypeptides as subunits of factor VIII. N-Terminal amino acid sequence analysis determined that the Mr 210 000 and 80 000 proteins are derived from the N- and C-terminal portions of factor VIII, respectively; Mr 90 000-180 000 polypeptides are derived from the Mr 210 000 polypeptide by C-terminal cleavages. Treatment of purified factor VIII with thrombin resulted in proteolysis of Mr 80 000-210 000 proteins and the generation of polypeptides of Mr 73 000, 50 000, and 43 000. Maximum coagulant activity of thrombin-activated factor VIII was correlated with the generation of these polypeptides. The proteolysis as well as activation of factor VIII by thrombin was found to be markedly dependent on CaCl2 concentration. Proteolysis of factor VIII with activated protein C (APC) resulted in degradation of the Mr 90 000-210 000 proteins with the generation of an Mr 45 000 fragment. This cleavage correlated with inactivation of factor VIII by APC. The Mr 80 000 protein was not degraded by APC. Factor Xa cleaved the Mr 80 000-210 000 factor VIII proteins, resulting in the generation of fragments of Mr 73 000, 67 000, 50 000, 45 000, and 43 000. Factor Xa was found to initially activate and subsequently inactivate factor VIII.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of factor VIII concentrate on malondialdehyde release by normal human platelets]

It is well known that Factor VIII concentrates affect platelet function both "in vitro" and "in vivo" but the mechanism of their action is poorly understood. Therefore the aim of the present work was to investigate a possible effect of these concentrates on prostaglandin synthesis by platelets, measured as the amount of released malondialdehyde (MDA), which is an index of Thromboxane A2 production. Our data suggest that Factor VIII concentrates have no effect on MDA release by platelets and on its inhibition by aspirin and heparin. In conclusion the effect of Factor VIII concentrates on platelets is not mediated by an increased synthesis of prostaglandins.     

Comparison of thawing of plasma by microwave or water bath: preliminary longitudinal biological study of hemostatic parameters

Exploration of haemostasis was performed on plasmas thawed in an experimental microwave oven comparatively to a 37 degrees C water bath. Factor VIII:R:Ag, procoagulant and antigenic fibrinogen, and Fg:C/Fg:Ag ratio were found to be significantly, slightly decreased with microwave thawing. Factor VIII:C and VIII:C/VIII:R:Ag ratio were found to be increased with microwaves. Antigenic fractions were decreased because of partial precipitation. In addition, Fibrinogen slightly lost its activity; on the contrary, factor VIIIC was activated by micro-waves. All this allows to select parameters for new experimental microwave ovens development.     

The interaction of the factor VIII/von Willebrand factor complex (VIII/vWf), with guanidinium-derivatized matrices.

Five different guanidinium (Gu)-derivatized agarose matrices were investigated for their potential in chromatographically resolving the Factor VIII/von Willebrand complex, VIII/vWf, fibrinogen, Fg, and fibronectin, Fn, from cryoprecipitate. Using conventional NaCl gradient methodology it was found that the order of elution of specific plasma proteins, and the yield of VIII/vWf, varied with the methods used to derivatize the agarose beads. Good yields of VIII:C (generally 30-45%) were obtained with Gu-matrices prepared by bis-oxirane coupling procedures. Cryoprecipitate binding studies showed that the capacity of Gu-Sepharose 4B, prepared by isourea modification of amino-Sepharose 4B, was 36 units VIII/vWf per ml matrix. The product, depleted of both Fg and Fn, had a specific activity of 2 units VIII:C per mg total protein, (yield 100% vWf:Ag and 47% VIII:C).     

The relationship of biological and immunological activities of factor VIII

Factor VIII is an essential blood clotting factor which consists of two protein moieties, each with distinct biological functions and antigenic determinants. The immunological markers were originally seen as indicators of the biological activities; however this view has been increasingly challenged. We have investigated the biological and immunological properties of Factor VIII to clarify these relationships. Plasma stored at room temperature for 21 days lost biological activity, but retained immunological activity: The procoagulant activity was reduced to 35% and the ristocetin cofactor activity to 75.4% of their original levels; but the reactivities of both procoagulant antigen and Factor VIII related antigen were maintained. A dissociation of activities was also demonstrated in serum, in which the procoagulant activity was 10% and the procoagulant antigen 72% of corresponding plasma values. These results indicate that the antigenic reactivities are not appropriate markers for Factor VIII biological activity.     

Donor selection for the production of factor XIII preparations

For the purpose of establishing a programme of plasmapheresis for manufacturing preparations containing factor VIII, investigations were made to check the expediency of selecting donors. Factor VIII activity (Factor VIII: C) was determined in a total of 165 donors of plasmapheresis. Dependencies of factor-VIII: C on blood group, age and influence of smoking were examined. Depending on the blood group (0 less than A, B, AB) the results found by us showed significant differences in factor-VIII: C. The results are discussed and compared with data in literature. A selection of donors is considered to be reasonable. Increases in gaining factor-VIII are possible by making a pre-selection according to blood groups or better by exact testing respectively.     

In vitro stability studies of a Factor IX concentrate (Bebulin)

Factor IX: C activity decay was studied in lyophilized concentrates (Bebulin, IMMUNO) stored at room temperature and in reconstituted preparations frozen and stored at -20 degrees C. A very slight, practically identical, decay of Factor IX: C was found in lyophilized concentrates kept at room temperature, in reconstituted lyophilized concentrates frozen and stored at -20 degrees C and lyophilized concentrates kept at +4 degrees C. At the end of the experiment, which was 4-5 months after the expiration date of the product, a 15-30% decay of Factor IX: C could be found in the concentrates with respect to initial levels.     

Factor VIII activity and factor VIII-associated antigen in healthy newborns and in newborns with stressing perinatal factors

Factor VIII coagulation activity (VIII:C) and factor VIII associated antigen (VIII:AGN) were determined in healthy newborns and in children with charging perinatal factors ("risk children"). VIII:C values of healthy newborns may be compared with those of grown-ups with normal coagulation. Risk children have somewhat higher values than newborns, the difference, however, being statistically not significant. The concentration of VIII:AGN is clearly increased in both groups on the first day of life. Moreover, VIII:AGN is being eliminated more slowly in risk children. The increased VIII:AGN concentrations are considered as a sequel of stress conditions caused by birth, whereas the discrepancy between VIII:C and VIII:AGN is due to a thrombin effect.     

Inactivation of human factor VIII by activated protein C: evidence that the factor VIII light chain contains the activated protein C binding site

Factor VIII is represented as a series of heterodimers composed of an 83(81) kDa light chain noncovalently bound to a variable size (93 to 210 kDa) heavy chain. Activated protein C inactivates factor VIII causing several cleavages of the factor VIII heavy chain(s). When factor VIII subunits were dissociated and component heavy and light chains isolated, the heavy chains were no longer a substrate for proteolysis by activated protein C. However, when factor VIII heavy chains were recombined with light chain, the reconstituted factor VIII activity was inactivated by activated protein C. The rate of factor VIII inactivation catalyzed by activated protein C was reduced by the presence of free light chain. The extent of this inhibition was dependent upon the concentration of light chain. Control experiments indicated that this protective effect of free light chain was not the result of inhibition of the activated protein C - lipid interaction. Fluorescence analysis demonstrated binding between the factor VIII light chain, chemically modified with eosin maleimide, and activated protein C, modified at its active site by dansyl-Glu-Gly-Arg chloromethyl ketone. Similar to proteolysis of factor VIII by activated protein C, this binding was dependent upon a lipid surface. Based upon the degree of fluorescence quenching, a spatial distance of 26 A was calculated separating the two fluorophores. These results demonstrate direct binding of activated protein C to the factor VIII light chain and suggest that this binding is an obligate step for activated protein C-catalyzed inactivation of factor VIII.     

Problems of conductor demonstration in haemophilia A: error possibilities in the determination of factor-VIII-associated antigen]

Difficulties in the detection of haemophilia A carriers by the determination of the ratio factor VII coagulation activity to factor VII antigen concentration are shown in part one of our investigations. The second part evaluates methodical parameters of the quantitative immunoelectrophoretic technique. According to our results reliable data can only be obtained under the following conditions: 1. At least three determinations of each sample are required and the mean value should be used as the final result. 2. Each gel plate should be calibrated separately 3. The calibration line should include values less than 100%. Factor VIII concentrates are not suitable for determination of the calibration curve, as higer dilution results in lower calculated concentration of the undiluted concentrate. Storage of pooled normal plasma at--25 degrees C is possible without significant loss of antigen concentration over 5 months. However, plasma samples of a single person show an unpredictable variation in the antigen concentration during storage over the same time.     

Inactivation of factor VIII by activated protein C and protein S

Factor VIII was inactivated by activated protein C in the presence of calcium and phospholipids. Analysis of the activated protein C-catalyzed cleavage products of factor VIII indicated that inactivation resulted from the cleavage of the heavy chains. The heavy chains appeared to be converted into 93- and 53-kDa peptides. Inactivation of factor VIII that was only composed of the 93-kDa heavy chain and 83-kDa light chain indicated that the 93-kDa polypeptide could be degraded into a 68-kDa peptide that could be subsequently cleaved into 48- and 23-kDa polypeptides. Thus, activated protein C catalyzed a minimum of four cleavages in the heavy chain. Activated protein C did not appear to alter the factor VIII light chain. The addition of protein S accelerated the rate of inactivation and the rate of all of the cleavages. The effect of protein S could be observed on the cleavage of the heavy chains and on secondary cleavages of the smaller products, including the 93-, 68-, and 53-kDa polypeptides. The addition of factor IX to the factor VIII-activated protein C reaction mixture resulted in the inhibition of factor VIII inactivation. The effect of factor IX was dose dependent. Factor VIII was observed to compete with factor Va for activated protein C. The concentration dependence of factor VIII inhibition of factor Va inactivation suggested that factor VIII and factor Va were equivalent substrates for activated protein C.     

A novel approach in potential anticoagulants from peptides epitope 558–565 of A2 subunit of factor VIII

Factor VIII, a human blood plasma protein, plays an important role during the intrinsic pathway of blood coagulation cascade after its activation by thrombin. The activated form of FVIII acts as cofactor to the serine protease Factor IXa, in the conversion of the zymogen Factor X to the active enzyme Factor Xa. The Ser⁵⁵⁸–Gln⁵⁶⁵ region of the A2 subunit of Factor VIII has been shown to be crucial for FVIIIa–FIXa interaction. Based on this, a series of linear peptides, analogs of the 558–565 loop of the A2 subunit of the heavy chain of Factor VIII were synthesized using the acid labile 2-chlorotrityl chloride resin and biologically evaluated in vitro by measuring the chronic delay of activated partial thromboplastin time and the inhibition of Factor VIII activity, as potential anticoagulants.     

Multimers of von Willebrand antigen in therapeutic factor VIII concentrates

By crossed immunoelectrophoresis (XIEP), the pattern of von Willebrand factor antigen (vWF:Ag) was investigated in six commercially available factor VIII (F VIII) concentrates and in normal human plasma. At least 5 subpopulations of vWF:Ag were recognized by XIEP in the therapeutic F VIII concentrates and in normal plasma. F VIII preparations high in ristocetin cofactor activity (vWF:RICof) and low in the ratio of vWF:Ag to vWF:RiCof were found to be similar in the multimeric structure of vWF:Ag to normal plasma. However, F VIII concentrates low in activity of vWF:RiCof and high in the ratio of vWF:Ag to vWF:RiCof were found to be deficient in the slowly migrating, high molecular weight multimers of vWF:Ag present in normal plasma.     

Production of Recombinant Human Factor VIII in Different Cell Lines and the Effect of Human XBP1 Co-Expression

Recombinant factor VIII is one of the most complex mammalian proteins and a biotechnology venture required for the treatment of hemophilia A. The complexity of the protein, post-translational modifications and limitations of expression elements make the production of active recombinant FVIII a challenge. Here we report the production of biologically active Factor VIII in two different cell lines, CHO and HepG2, by transient transfection. Two expression vectors based on the CMV promoter were used: one harboring CMV Intron A (InA) and the other without it. To bypass difficulties in secretion, we also studied the influence of co-expression of the human splice isoform of the XBP1 gene. We report the production of recombinant FVIII possessing bioengineered FVIII heavy and light chains, linked by a minimal B domain. In our study, HepG2, a human hepatocyte cell line, expressed Factor VIII ten-fold more than a CHO cell line, and in HepG2 cells, the expression of XBP1 improved Factor VIII activity. For CHO cells, expression was improved by the presence of InA, but no further improvement was noted with XBP1 co-expression. These data suggest that the minimal B domain rFVIII preserves Factor VIII biological activity and that different expression elements can be used to improve its production.     

Interaction of factor VIII-von Willebrand Factor with phospholipid vesicles.

The interaction of Factor VIII-von Willebrand Factor with phospholipid vesicles has been studied by using sucrose-density-gradient ultracentrifugation. When purified Factor VIII-von Willebrand Factor was run alone. Factor VIII activity and Factor VIIIR-Ag sedimented together to the lower half of the tube. Addition of phosphatidylserine/phosphatidylethanolamine vesicles at concentrations above 250 microgram/ml resulted in complete separation of Factor VIII activity and Factor VIIIR-Ag, the former appearing with the phospholipid on the top of the tube and the latter sedimenting as before. This separation was obtained even in the presence of proteinase inhibitors. Activation of Factor VIII-von Willebrand Factor by thrombin resulted in formation of a slow sedimenting component containing essentially all the Factor VIII activity, whereas the Factor VIIIR-Ag sedimented towards the bottom of the tube as before. The thrombin-induced Factor VIII activity was strongly bound to phospholipid vesicles as determined by density-gradient centrifugations at various Factor VIII concentrations and low concentrations of phospholipid. Based on certain assumptions a dissociation constant of 2.5 nM was calculated, a mechanism for the formation in vivo of the Factor X-activator complex is suggested.     

Factor VIII coagulant activity and factor VIII-related antigen released from isolated perfused human spleens.

Eight human spleens were perfused for up to 65 h at normothermia and the coagulant Factor VIII activity measured in the perfusate. In addition, in three experiments Factor VIII-related antigen was determined in the perfusate. Although the spleens were pathologically enlarged and the normal structure involved by different diseases, all spleens released Factor VIII coagulant activity and Factor VIII-related antigen. On average the total amount of Factor VIII coagulant activity released was equivalent to that of 3.5 l of human plasma.