Pharmacokinetics, efficacy and safety of Humate-P® in von Willebrand disease

In a pharmacokinetic study with Humate-P^® including six patients with various types of von Willebrand disease, a median half-life of 11.3 h for vWF:RCoF and of 15.2 h for vWF:Ag was found. The median value of in vivo recovery (IVR) was estimated for vWF:RCoF as 2.10 IU dL⁻¹ plasma per 1 substituted IU kg⁻¹ b.w. (or 73%), for vWF:Ag as 1.88 IU dL⁻¹ plasma per 1 substituted IU kg⁻¹ b.w. (or 69%); and for FVIII:C as 2.69 IU dL⁻¹ plasma per 1 IU kg⁻¹ b.w. (or 99%). Transient postinfusion shortening or normalization of previously prolonged bleeding time was observed in all patients. In a retrospective study involving 97 patients with various von Willebrand disease types, clinical efficacy and safety of treatment with Haemate-P^® in 73 surgical interventions, 344 separate bleeding events, 93 other events and 20 cycles of prophylactic treatment were evaluated. The clinical efficacy was rated good to excellent in 99% of the surgeries, in 97% of the bleeding episodes, in 86% of the other events, and in all prophylactic treatments. The overall tolerability was good. Adverse events possibly or probably associated with use of Humate-P^®/Haemate-P^® were rare, of non-serious nature and mild to moderate in their intensity.     

Characterization of factor VIII/von Willebrand factor concentrates using a modified method of von Willebrand factor multimer analysis

In order to provide patients with von Willebrand disease a factor VIII (FVIII)/von Willebrand factor (vWF) concentrate of reproducible quality, an SDS-agarose gel electrophoresis method has been established to determine the content of the high molecular weight multimers (band 11 and higher) of vWF. This method has been used to characterize the content of high molecular weight vWF multimers in Humate^® P/Haemate^® P, a commercial FVIII/vWF concentrate. The average content of high molecular weight vWF multimers of 47 batches of Humate^® P/Haemate^® P has been determined to be 84.1% of the corresponding bands in normal human plasma. Use of this multimer analysis method for the characterization of five further commercial products revealed clear differences with respect to the high molecular weight vWF multimer content. Furthermore, there is a linear correlation ( r ² = 0.73) between the content of high molecular weight vWF multimers and the specific activity of vWF (determined as vWF:RCoF/vWF:Ag). The method described here for analysis of the content of high molecular weight vWF multimers is a reliable and reproducible method to characterize this class of factor concentrates with respect to vWF multimer composition.     

Characterization of von Willebrand factor in factor VIII concentrates

Commercial concentrates of factor VIII (FVIII) were analyzed in order to 1) determine the effects of viral inactivation on von Willebrand factor (vWF); 2) evaluate the vWF content of the new, immunopurified concentrates; and 3) assess their potential for correcting the long bleeding time of von Willebrand disease (vWD). Included in our study were products that had been treated to inactivate viruses; older, untreated products; and the new, immunopurified concentrates. We measured von Willebrand factor antigen (vWF:Ag), ristocetin cofactor activity (RCoF), and vWF multimeric and subunit composition. A newly developed radioimmunoassay (RIA) was used to quantitate vWF:Ag. The vWF:Ag content varied from 0.083 micrograms/IU FVIII:C for Hemofil M to 32.2 micrograms/IU FVIII:C for Humate-P, whereas pooled normal human plasma (NHP) contained 6.3 micrograms/IU FVIII:C. The RCoF varied from 0.0007 to 2.09 U/IU FVIII:C, with the immunopurified concentrates having the lowest values and Humate-P the highest. The ratio of RCoF to vWF:Ag ranged from 11 to 96 U/mg, as compared to a ratio of 160 for NHP. All of the concentrates lacked the largest vWF multimers, and all had abnormal triplet patterns. Modest differences between some untreated concentrates and their treated counterparts were noted. As expected, the immunopurified concentrates had much lower levels of all vWF activities than the conventionally prepared products. Our data suggest that none of the concentrates have as great a capacity as NHP to correct the prolonged bleeding time of von Willebrand disease.     

Haemostatic treatment in connection with surgery in patients with von Willebrand disease

Haemostatic treatment in patients with von Willebrand disease (vWD) in connection with surgery aims at normalizing the haemostatic defect in order to avoid bleeding complications. Factor VIII (FVIII) levels in plasma must be normalized in connection with major surgery, whereas the bleeding time is more important for mucous membrane bleedings. Most patients respond well to treatment with desmopressin which stimulates the endogenous release of FVIII and von Willebrand factor (vWF) and shortens the bleeding time. Non-responders to desmopressin are substituted with a plasma-derived factor concentrate which contains vWF and FVIII. This paper includes a summary of retrospective data from the last 10 years on haemostatic treatment in connection with surgery from four haemophilia centres in Sweden and Denmark on 40 invasive procedures in 27 vWD patients and on one normal delivery. If a FVIII-containing concentrate is given prior to surgery a dose of 30–40 IU VIII:C kg⁻¹ will normalize FVIII levels in most severe cases. If a pure vWF concentrate is used, a dose of 40–50 IU RCoF kg⁻¹ will normalize RCoF in most cases, but FVIII levels will not be normalized until after about 12 h or later. Repeated doses of FVIII-vWF concentrate may lead to very high levels of FVIII in plasma because of the combined effect of the exogenous FVIII-substitution and the endogenous FVIII-release induces by the infused vWF. Dosage should be adjusted according to FVIII levels in plasma.     

Evaluation of recombinant von Willebrand factor in a canine model of von Willebrand disease

Dutch Kooiker dogs with hereditary von Willebrand disease have undetectable levels of von Willebrand factor (vWF), resulting in spontaneous haemorrhage of mucosal surfaces similar to the clinical picture of von Willebrand disease in humans. We used this canine model of von Willebrand disease to study the in vivo effects of a new recombinant von Willebrand factor (rvWF) preparation that contained all species of vWF multimers compared with a rvWF fraction containing only low molecular weight multimers (LMW-rvWF) and with a plasma-derived factor VIII/vWF concentrate (pdvWF). Administration of rvWF in these vWF-deficient dogs resulted in a vWF:Ag half-life of 21.6 h in one dog and 22.1 h in a second dog. Administration of pdvWF resulted in a half-life for vWF:Ag of 7.7 h, and LMW-rvWF, 9 h. The in vivo recovery of vWF:Ag after administration of rvWF was 59%, 64% and 70% in three dogs, respectively; 33% after pdvWF, and 92% after LMW-rvWF. The in vivo recovery of ristocetin cofactor (RCoF) was 78%, 110% and 120% for rvWF, and 25% for pdvWF. Both rvWF and pdvWF caused increases in FVIII. Although no effect was seen on bleeding time at the dosages used, the rate of blood flow from cuticle wounds was reduced after a single bolus administration of rvWF. The rvWF was able to control a severe nose bleed in one dog.     

Prednisone and low-dose activated prothrombin complex concentrates for FVIII inhibitor in nonhaemophilic patients

Eight nonhaemophilic patients with factor VIII (FVIII) inhibitors were reported. There was no difference in sex distribution. Median age at diagnosis was 62 years (ranging from 14 to 73 years). No associated disorders were revealed and all the patients were presented with severe muscular or arthral bleeding. Inhibitor titre was measured by the Bethesda method, which were 6.4, 126.0, 155.0, 4.8, 56.0, 13.5, 35.0 and 150.0 BU mL⁻¹, respectively, at diagnosis. FVIII:C levels were less than 1 U dL⁻¹ in seven patients and less than 2 U dL⁻¹ in one patient. The median vWF:Ag level was 210% (ranging from 80% to 340%). All the patients had good response to activated prothrombin complex concentrates for acute bleeding episodes and prednisone for inhibitor elimination. Inhibitors completely eliminated in seven patients within a follow-up duration over 1 year, and one patient died of intracranial haemorrhage when her inhibitor titre decreased to 4.5 BU mL⁻¹ and FVIII:C increased to 21 U dL⁻¹.     

Bleeding prophylaxis for major surgery in patients with type 2 von Willebrand disease with an intermediate purity factor VIII-von Willebrand factor concentrate (Haemate-P).

The parameters to diagnose von Willebrand disease (vWD) include factor VIII coagulant activity (FVIII:C), von Willebrand factor antigen (vWF:Ag), von Willebrand factor ristocetin cofactor activity (vWF:RCo), and von Willebrand factor collagen binding activity (vWF:CB). Type 2 vWD is associated with a moderate bleeding diathesis due to low levels of vWF:RCo and vWF:CB as compared with near normal or normal values for FVIII:C and vWF:Ag. As the factor VIII/von Willebrand factor (vWF) concentrate, Haemate-P, is featured by a vWF:RCo/FVIII:C ratio of about 2.2, the recommended loading dose of 50 U/kg FVIII:C followed by 25 U/kg FVIII:C every 12 h for several days for bleeding prophylaxis in type 2 vWD patients undergoing major surgery demonstrated a predicted significant over-treatment reaching vWF:RCo levels above 2 U/ml. Therefore, we restricted Haemate-P substitution for major surgery to one loading dose of 40-50 U/kg FVIII:C (88-110 U/kg vWF:RCo) followed by 15-20 U/kg FVIII:C (33-44 U/kg vWF:RCo) every 12 h for several days and evaluated this strategy in a prospective pharmacokinetic and efficacy study for bleeding prophylaxis in five type 2 vWD patients. Pre-treatment and peak levels (1 h after Haemate-P loading dose) rose from 0.43-0.66 to 1.5-2.5 U/ml for FVIII:C, from 0.23-0.45 to 1.5-2.5 U/ml for vWF:Ag, from 0.10-< 0.20 to 1.5-2.5 U/ml for vWF:RCo, and from < 0.05-0.10 to 1.0-2.0 U/ml for vWF:CB. Mean in vivo recoveries per transfused IU FVIII:C/kg body weight were 3.2% for FVIII:C, 3.9% for vWF:RCo, and 2.8% for vWF:CB. Mean in vivo recoveries per transfused IU vWF:RCo/kg were 1.45% for FVIII:C, 1.7% for vWF:RCo and 1.25% for vWF:CB. The biological half-life times after transfused Haemate-P were about 12 h for both vWF:RCo and vWF:CB. Based on these pharmacokinetic data, we propose to adapt the loading dose factor VIII/vWF concentrate (Haemate-P) to 60-80 U/kg vWF:RCo followed by 30-40 U/kg vWF:RCo every 12 h for no longer than several days (less than 1 week) for bleeding prophylaxis during major surgery or trauma, and to one loading dose of 40-60 U/kg vWF:RCo for minor surgery, trauma or mucotaneous bleedings in patients with type 2 vWD unresponsive to DDAVP.     

Pharmacokinetics of recombinant factor VIII (Kogenate-FS®) in children and causes of inter-patient pharmacokinetic variability

Summary.  Understanding the pharmacokinetics (PK) of factor VIII (FVIII) is important in the management of patients with haemophilia A. We studied the PK of FVIII in order to determine aetiological factors contributing to PK variability of FVIII in children.
Twenty children with haemophilia A (mean age 12.8 years) were administered a single bolus of 50 U kg⁻¹ of recombinant FVIII (rFVIII; Kogenate-FS^®, Bayer).
The mean incremental FVIII recovery was 1.87 (U mL⁻¹)/(U kg⁻¹) (range: 1.25–2.76) and the mean FVIII half-life was 10.7 h (range: 7.8–15.3). FVIII recovery was positively correlated with body surface area (BSA; P  = 0.04). FVIII half-life was positively correlated with preinfusion levels of von Willebrand factor antigen (VWF:Ag) ( P  = 0.0001) and was reduced in patients ( n  = 6) with very low FVIII inhibitor titres (<0.5 BU) vs. those ( n  = 14) with negative inhibitor titres ( P  = 0.06).
These observations suggest that (i) young children with haemophilia in comparison with adults have a low recovery of FVIII and that this might be explained by differences in body composition (BSA, plasma volume), (ii) levels of VWF:Ag may explain some of the differences in the half-life and clearance of FVIII and (iii) very low inhibitor titres, previously regarded as clinically insignificant, may actually be significant and should be evaluated in the context of PK studies.     

Optimizing therapy with factor VIII/von Willebrand factor concentrates in von Willebrand disease

In von Willebrand disease, the main goals of treatment are to correct the dual defect of haemostasis caused by a reduced or abnormal von Willebrand factor (vWF), i.e. the prolonged bleeding time (BT) and the deficiency of factor VIII coagulant activity (FVIII:C). The synthetic vasopressin analogue, desmopressin (DDAVP), has reduced the need for transfusions in most of the mild forms of von Willebrand disease but DDAVP is ineffective in type 3 and in other severe cases of types 1 and 2 von Willebrand disease. For many years cryoprecipitate has been the mainstay of replacement therapy but, after the introduction of virucidal methods, concentrates containing FVIII/vWF have been considered much safer than cryoprecipitate and proposed in von Willebrand disease management. FVIII/vWF concentrates have been produced and tested by many authors but there is only one report describing four virus-inactivated FVIII/vWF concentrates evaluated in a cross-over randomized trial. According to these in vitro and pharmacokinetic data, the following information can be derived: (a) no FVIII/vWF concentrate had an intact multimeric structure similar to that of normal plasma or of cryoprecipitate; (b) all FVIII/vWF concentrates were equally effective in attaining normal and sustained levels of FVIII:C postinfusion, although peak levels were more delayed in the concentrate devoid of FVIII:C; (c) no FVIII/vWF concentrate consistently normalized the BT in a sustained fashion. On the other hand, clinical haemostasis can be achieved in the management of bleeding episodes and of surgery for most of von Willebrand disease cases regardless of whether the BT is corrected; in the few rare cases with mucosal bleeding not controlled by FVIII/vWF concentrates, infusion of DDAVP or platelet concentrates can be administered in addition.     

Influence of von Willebrand factor on the reactivity of human factor VIII inhibitors with factor VIII

In order to determine the difference in reactivity of factor (F) VIII inhibitors against the FVIII/von Willebrand factor (vWF) complex and against vWF-deficient FVIII, we investigated a panel of 10 antibodies to FVIII from multitransfused individuals with severe haemophilia A and other pathologies. Immunoblotting of purified FVIII and purified thrombin-cleaved FVIII revealed that in all cases inhibitor epitopes could be localized in the heavy chain (A2 subunit) while in four cases they were also present in the light chain. One of the FVIII inhibitors remained unclassified. The effect on FVIII:C of purified IgG from inhibitor plasmas was tested against a high purity FVIII/vWF concentrate and a monoclonally purified FVIII concentrate with only trace contents of vWF, by two different functional assays. Our results suggest that for those inhibitors showing A2 plus light chain (LC) reactivity, the IgG concentration required to inhibit 50% of FVIII activity in vitro is higher for the FVIII/vWF complex than for the vWF-deficient FVIII. We conclude that there might be a protective role of vWF (at least in vitro) against FVIII inhibitors with A2 and LC subunit specificity.     

Efficacy and safety of a factor VIII–von Willebrand factor concentrate 8Y: stability, bacteriological safety, pharmacokinetic analysis and clinical experience

The present study was undertaken to evaluate stability, pharmacokinetic profile and efficacy of continuous infusion of 8Y in patients with different types of von Willebrand disease (vWD). Following reconstitution, 8Y levels of von Willebrand factor ristocetin cofactor (vWF:Rco), vWF antigen and factor VIII coagulant activity (FVIII:C) decreased to about 80% of the baseline levels; addition of low molecular weight heparin decreased the level of FVIII:C even further. Reconstituted 8Y was found to be sterile for up to 6 days postreconstitution. Ten vWD patients (four with type 2A, three with type 3, two with type 1 and one with 2N) underwent pharmacokinetic analysis. The recovery of vWF: RCo was significantly lower in patients with type 3 vWD (1.4 +/- 0.05% U(-1) kg(-1)) compared with that of the patients with types 1 (2.3 +/- 0.52% U(-1) kg(-1)) or 2A (2.0 +/- 0.06% U(-1) kg(-1)) vWD (P = 0.015). Type 3 vWD patients exhibited significantly higher vWF:RCo clearance (5.1 +/- 1.1 mL kg(-1) h(-1)) compared with that of patients with type 2A (2.8 +/- 0.7 mL kg(-1) h(-1)) and type 1 (2.6 +/- 1.0 mL kg(-1) h(-1)) vWD (P = 0.028). Accordingly, terminal half-life was lower in patients with type 3 vWD (8.0 +/- 0.6 h(-1)) compared with type 2A (12.7 +/- 5.9 h(-1)) or type 1 (14 +/- 1.2 h(-1)) vWD patients. Multimeric pattern of vWF from patients' plasma was similar to that of 8Y. In two patients treated with 8Y by continuous infusion for prevention or treatment of bleeding haemostasis was achieved. Thus, 8Y is suitable and haemostatically effective for continuous infusion treatment in patients with vWD.     

Pharmacokinetics of von Willebrand factor and factor VIIIC in patients with severe von Willebrand disease (type 3 VWD): estimation of the rate of factor VIIIC synthesis

Nine patients (10 infusions) with a confirmed diagnosis of type 3 VWD were infused with von Willebrand factor (human), a preparation of von Willebrand factor (VWF) with a very low factor VIII content. Each patient was infused with one dose of approximately 50 or 100 iu ristocetin cofactor activity (VWF:RiCoF) per kg body weight. Bleeding times were performed during the 24 h period after infusion. Plasma samples were obtained over the 96 h period after infusion and were analysed for factor VIII coagulant activity (FVIIIC), VWF:RiCoF, von Willebrand factor antigen (VWF:Ag), and multimers. The FVIIIC data were analysed by non-linear least-squares analysis assuming constant FVIIIC 'synthesis' and exponential decay. The VWF data were fitted for exponential decay. The average decay rates for FVIIIC, VWF:RiCoF and VWF:Ag were 0.041, 0.061 and 0.056 respectively. The average calculated 'synthesis' rate for FVIIIC was 6.4 u/dl/h. The synthesis of FVIIIC was slightly faster and the decay slightly slower following the infusion of 100 iu VWF:RiCoF/kg than of 50 iu VWF:RiCoF/kg. Correction of the bleeding time was strongly dose dependent. At 4 h post infusion the median bleeding time was 9 min following a dose of 50 iu VWF:RiCoF/kg versus 3 min with a dose of 100 iu VWF:RiCoF/kg. There was no decrease in the bleeding time until the level of VWF:Ag or VWF:RiCoF reached >100 u/dl.     

Acquired von Willebrand disease and storage pool disease in chronic myelocytic leukemia

Platelet function was evaluated in 20 patients with chronic myelocytic leukemia (CML), all Ph positive. Seven showed abnormal epinephrine-induced aggregation, while four had impaired both ADP- and collagen-induced aggregation. The platelets of all patients aggregated with arachidonic acid, thus ruling out cyclooxygenase or lipoxygenase deficiency. The intracellular concentrations of ATP and ADP were significantly below normal, and the ratio of ATP/ADP was greater than normal in all 12 patients. ATP released from platelets by Lumi-aggregometer was reduced. In four patients with abnormal ristocetin-induced aggregation, vWF:Ag, RCoF, and FVIII:C were all reduced. No significant inactivation of factor VIII was induced in normal plasma by incubation with patient's plasma. The crossed immunoelectrophoretic analysis revealed that vWF:Ag in these patients was mainly composed of more anodic component as compared with that of normal plasma. The ratio of vWF:Ag/RCoF was significantly greater than normal. A marked increase of factor VIII and a rapid return of vWF:Ag and RCoF to the baseline after the 1-deamino-8-arginine vasopressin (DDAVP) infusion were observed. Transient increase in vWF:Ag after the infusion of DDAVP appeared with less anodic forms and in the same relative proportion as that in normal plasma. The present study shows that in some patients with CML storage pool disease occurs with acquired von Willebrand disease.     

Pharmacokinetics and hemostatic effect of different factor VIII/von Willebrand factor concentrates in von Willebrand's disease type III

Summary Four different plasma-derived concentrates composed of coagulation factor VIII (FVIII) and von Willebrand factor (vWF) of varying quality (Hemate-P, Behring; Profilate, Alpha; and FVIII-VHP-vWF, C.R.T.S Lille), or almost purified vWF (Facteur Willebrand, C.R.T.S Lille) and one recombinant FVIII concentrate (Recombinate, Baxter) were given, in doses of 30–60 IU VIII:C/kg or 70–110 IU RCof/kg, to five patients with von Willebrand's disease type III, in order to evaluate the role of the vWF in factor FVIII concentrates. All plasma concentrates except Profilate had a multimeric vWF pattern almost similar to that of normal plasma. Bleeding time (b.t.), VIII:C, vWF: Ag, ristocetin cofactor activity, and multimeric pattern of the plasma-vWF were followed for 72 h. Both Duke b.t. and the multimeric pattern in plasma normalized after infusion of Hemate-P, FVIII-VHP-vWF, and Facteur Willebrand and, to a lesser extent, after Profilate. As expected, in response to Recombinate there was no effect on primary hemostasis, and the half-life of FVIII procoagulant activity (VIII:C) was very short. Normalization of the vWF is important not only for improving the primary hemostasis, but also for maintaining the plasma FVIII concentration on a high level, both by reducing the elimination rate of infused FVIII and via a secondary release of endogenous FVIII. If a prompt hemostatic effect is required, we recommend a concentrate containing both FVIII and all vWF multimers, but for prophylactic treatment, pure vWF may be used.     

Recombinant factor VIIa in continuous infusion during central line insertion in a child with factor VIII high-titre inhibitor

Recombinant factor VIIa (rFVIIa) is a recently added new tool for the treatment of haemophilia patients with inhibitors. A major drawback in the use of rFVIIa is its short half-life, which necessitates frequent bolus injections. Thus the use of rFVIIa in continuous infusion appears to be a good alternative. We describe the use of rFVIIa, administered by continuous infusion with a minipump during the insertion of a central venous catheter in a child with a high-titre factor VIII inhibitor. rFVIIa was administered as an intravenous bolus (90 μg kg⁻¹ [4.5 kIU kg⁻¹]), 1 h prior to central line insertion, after which the continuous infusion was immediately started for 5 days. The infusion rate was based on the clearance obtained from a previous pharmacokinetic study. Effective haemostasis and normal healing of surgical incisions were achieved after central line insertion. No local thrombophlebitis nor evidence of generalized activation of the coagulation cascade was observed. Single-dose pharmacokinetic parameter values were clearance (Cl) 34.6 mL h⁻¹ kg⁻¹, volume of distribution (Vd) 40.6 mL kg⁻¹ and mean residence time (MRT) 1.17 h. The recovery was 2.27% U⁻¹ kg⁻¹. rFVIIa showed a monophasic decay. Cl during continuous infusion was 23.4 ± 6.9 mL h⁻¹ kg⁻¹. The administration of rFVIIa by continuous infusion is effective, safe and more convenient when compared to other clotting factors. Moreover, continuous infusion provides significant economic savings (77% decrease in rFVIIa requirements).     

Common inhibitory effects of human anti-C2 domain inhibitor alloantibodies on factor VIII binding to von Willebrand factor

Summary. Factor VIII (FVIII) Inhibitor alloantibodies obtained from seven severe haemophilia A patients were examined for their binding regions and their effects on FVHI binding to von Willebrand factor (vWF). Immunoblotting analysis with a panel of recombinant fragments demonstrated that the binding regions of antibodies in cases 1-5 were contained in the C2 domain of the light chain. Antibodies from cases 1 and 2, which recognized an epitope within residues 2248-2312, completely inhibited FVIII/ vWF binding in an FXISA (IC₅₀: 5-0 and 9-0μg/ml, respectively). Antibodies from case 3 recognizing 2170-2312 and case 5 recognizing 2170-2327 also inhibited FVIII/vWF binding (IC₅₀:110 and 400μg/mI, respectively). Case 4 antibodies recognizing 2218-2307 showed barely detectable inhibition and cases 6 and 7 antibodies recognizing the 44 kD heavy chain, did not inhibit. Our results demonstrate that all anti-C2 alloantibodies with epitopes that extend to the residue 2312 inhibit vWF binding and that an overlap of the inhibitor epitope with residues 2308-2312 is critical for maximal inhibition of vWF binding. Prevention of FVIII/vWF binding appears to be a common property of anti-C2 domain inhibitor alloantibodies.     

Performance of recalibrated ReFacto® laboratory standard in the measurement of FVIII plasma concentration via the chromogenic and one-stage assays after infusion of recalibrated ReFacto® (B-domain deleted recombinant factor VIII)

Summary.  The use of ReFacto Laboratory Standard ( RLS ) in the one-stage clotting assay was proposed to reduce the underestimation of factor VIII (FVIII) plasma concentration after the infusion of 'ReFacto^®' (B-domain deleted recombinant FVIII) in haemophilia A patients. Both ReFacto^® and RLS were recently recalibrated, with the resulting materials containing approximately 20% more protein than the previous products. The aim of this study was to evaluate the performance of recalibrated RLS in the measurement of FVIII plasma concentration after the infusion of recalibrated ReFacto^®. In 13 severe haemophilia A patients, 25 IU kg⁻¹ of ReFacto ^® were injected intravenously. Venous blood samples were collected at 0.25, 0.5, 1, 3, 6, 9, 24, 28 and 32 h after the end of the infusion. Pharmacokinetic parameters were measured for the chromogenic and one-stage assays using International Plasma Standard (IPS) and RLS for both assays and assuming a non-compartmental drug disposition. Comparisons among assays and standards were performed using anova . Pharmacokinetic estimates obtained with the chromogenic method were in agreement with those published in the literature. The one-stage method was confirmed to be more sensitive to lower plasma concentrations of FVIII. The measured maximum plasma concentration ( C _max ) was slightly higher than theoretical values and independent of the assay used. C _max , area under the curve ( AUC) and volume of distribution at steady state ( V _ss ) presented non-significant differences among the methods and standards used. The clinical utility of RLS in the evaluation of FVIII concentration after the infusion of ReFacto^® seems to be reduced since recalibration of the product.     

von Willebrand factor contributes to longer half‐life of PEGylated factor VIII in vivo

PEGylation of B‐domain deleted factor VIII (PEG‐FVIII‐BDD) prolongs the half‐life of the molecule by approximately twofold in animals (Mei et al., Blood 2010; 116 : 270). To investigate the role of von Willebrand factor (vWF) in the catabolism of PEG‐FVIII‐BDD in vivo, a FVIII‐BDD mutant (F8V), which is incapable of binding vWF, was generated by deleting the vWF‐binding region in the a3 domain of FVIIII‐BDD. F8V was expressed, purified and PEGylated by site‐specific conjugation. The biochemical and biological properties of F8V and PEGylated F8V (PEG‐F8V) were evaluated in vitro and in vivo. The specific activity of purified F8V by a chromogenic assay was similar to FVIII‐BDD and PEGylation had minimal impact on the specific activity of F8V in this assay. Analysis by Biacore indicated that both F8V and PEG‐F8V display greatly reduced vWF binding in vitro. Pharmacokinetic studies in FVIII knockout (HaemA) mice showed that the terminal half‐life (T_1/2) of F8V was dramatically reduced relative to FVIII‐BDD (0.6 h vs. 6.03 h). PEGylation of F8V promoted a significant increase in T_1/2, although PEGylation did not fully compensate for the loss in vWF binding. PEG‐F8V showed a shorter T_1/2 than PEG‐FVIII‐BDD both in HaemA mice (7.7 h vs. 14.3 h) and in Sprague‐Dawley male rats (2.0 ± 0.3 h vs. 6.0 ± 0.5 h). These data demonstrated that vWF contributes to the longer T_1/2 of PEG‐FVIII‐BDD. Furthermore, this suggests that the clearance of the FVIII:vWF complex, through vWF receptors, is not the sole factor which places an upper limit on the duration of PEG‐FVIII circulation in plasma.     

The determination of von Willebrand factor activity by collagen binding assay

A new collagen binding assay has been developed for the determination of the functional activity of human von Willebrand factor based on the following principle: pepsin-digested type III collagen from human placenta was covalently immobilized on a microtitre plate. Binding of collagen to the microtitre plate was carried out in neutral phosphate buffer within 1 h. A collagen concentration of 3 μg mL^–1 was sufficient to achieve optimal coating. After drying, the coated microtitre plates remained stable for months without losing their vWF-binding properties and could be incorporated into a ready-to-use kit. The suitability of various types of collagen for use in this assay was evaluated by simulating the binding of vWF to collagen immobilized on the microtitre plate by using surface plasmon resonance technology with collagen immobilized on a sensor chip. vWF was most effectively bound to pepsin-digested type III collagen from human placenta. The assay thus comprises the following steps: (1) serial dilutions of a vWF reference preparation and vWF-containing samples are prepared and bound to a microtitre plate which is precoated with collagen; (2) vWF is detected with a polyclonal antibody; (3) the substrate reaction is photometrically measured with an ELISA reader. This test is highly specific and sensitive for vWF (detection limit: 10 ng mL^–1). The collagen binding activity measured corresponds to the degree of multimerization of vWF. The high sensitivity and the short time needed to carry it out may make it useful for clinical diagnosis and for the measurement of the functional activity of vWF in factor concentrates. In certain applications it may represent a suitable replacement for the ristocetin cofactor assay.     

Undetected factor VIII in a patient with type 3 von Willebrands disease mistaken as severe haemophilia A

Summary.  von Willebrand disease (VWD) type 3 is a rare disorder characterized by absent or <0.1 UmL⁻¹ of ristocetin cofactor (VWF:RCo), and a very low level of factor VIII (FVIII:C). A total absence of FVIII:C has never been reported in type 3 VWD. This case illustrates the effect of severe von Willebrand factor (VWF) deficiency on the factor VIII level.