Autoantibody to factor VIII that has less reactivity to factor Vlll/von Willebrand Factor Complex

To determine the difference in reactivity of factor Vlll (FVIII) inhibitor to FVlll/von Willebrand Factor (vWF) complex and FVlll free of vWF, an autoantibody to FVlll light chain was tested. A patient (1-3) suffered from autoimmune hemolytic anemia with autoantibody to FVIII. Epitope specificity of the patient's IgG (1-3 IgG) was shown to be the C2 domain of FVlll light chain (2170-2332) by Western blotting using recombinant FVlll deletions expressed in Escherichia coli. The inhibitory effect on FVlll procoagulant activity (VIII :C) of 1-3 lgG was tested against a conventional FVlll concentrate; Haemate P, a monoclonal antibody-purified FVlll concentrate; Hemofil M, and a recombinant FVlll (rFVIII); Kogenate. 1-3 lgG showed only 1.3 BU/mgIgG for Haemate P, in contrast to 20 BU/mglgG for both Hemofil M and Kogenate. The ratio of VIII:C/vWF:Ag in Haemate P and Hemofil M was 1/3.43 and 1/0.01, respectively, while Kogenate did not contain vWF. The inhibitory effect of the 1-3 IgG was then compared with Kogenate and its complex with vWF. The inhibitory effect was decreased against the rFVlll by forming a complex with vWF. from 22 BU/mglgG to o.5 BU/mgIgG. Fab from the 1-3 IgG had the same effect. In addition, vWF showed a protective effect on FVlll inactivation by the 1-3 IgG in a dose dependent manner. Fifty-nine percent of residual VIII:C was retained in the presence of 8 U/ml of vWF after 1 hr incubation with 1-3 lgG. These results suggested that vWF could compete with the 1-3 IgG for binding to FVIII. © 1995 Wiley-Liss, Inc.     

Antifactor VIII antibody inhibiting allogeneic but not autologous factor VIII in patients with mild hemophilia A

Two unrelated patients with the same Arg2150His mutation in the factor VIII (FVIII) C1 domain, a residual FVIII activity of 0.09 IU/mL, and inhibitor titres of 300 and 6 Bethesda Units, respectively, were studied. Further analysis of patient LE, with the highest inhibitor titer, showed that (1) plasma or polyclonal IgG antibodies prepared from LE plasma inhibited the activity of allogeneic (wild-type) but not of self FVIII; (2) the presence of von Willebrand factor (vWF) increased by over 10-fold the inhibitory activity on wild-type FVIII; (3) the kinetics of FVIII inhibition followed a type II pattern, but in contrast to previously described type II inhibitors, LE IgG was potentiated by the presence of vWF instead of being in competition with it; (4) polyclonal LE IgG recognized the FVIII light chain in enzyme-linked immunosorbent assay and the recombinant A3-C1 domains in an immunoprecipitation assay, indicating that at least part of LE antibodies reacted with the FVIII domain encompassing the mutation site; and (5) LE IgG inhibited FVIII activity by decreasing the rate of FVIIIa release from vWF, but LE IgG recognized an epitope distinct from ESH8, a murine monoclonal antibody exhibiting the same property. We conclude that the present inhibitors are unique in that they clearly distinguish wild-type from self, mutated FVIII. The inhibition of wild-type FVIII by LE antibody is enhanced by vWF and is associated with an antibody-dependent reduced rate of FVIIIa release from vWF.     

In vitro reactivity of factor VIII inhibitors with von Willebrand factor in different commercial factor VIII concentrates

A relevant aspect in the treatment of patients with hemophilia A (HA) presenting inhibitor against factor VIII (FVIII) is the different antigenicity of FVIII used for replacement therapy. The aim of the study was to assess the effect of different products, with variable von Willebrand factor (vWF) concentration, in preventing the binding of inhibitor to FVIII. The reactivity of inhibitors from plasma of 18 patients with HA versus three commercial concentrates containing different amounts of vWF was compared. The results show that increasing amounts of vWF might have a protective effect on the transfused FVIII inactivation.     

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.     

Variation in factor VIII inhibitor reactivity with different commercial factor VIII preparations

Summary. During treatment of a haemophilia A patient with a high-responding inhibitor against factor VIII coagulant activity (VIII:C), we observed a difference in recovery of VIII:C depending upon which factor concentrate was infused. Inhibitor plasma samples or IgG fraction from seven patients were tested against a panel of seven different commercially available factor VIII concentrates of which five were plasma-derived and two recombinant. In two of the plasma samples, inhibitor titres manifested a wide range of values depending upon which concentrate was used in the test system. Thus, inhibitor neutralization was less and VIII:C recovery greater when factor VIII concentrates containing large amounts of von Willebrand factor were used than when highly purified concentrates containing no von Willebrand factor or only trace amounts were used. In both of these two patients the inhibitor was directed against the light chain of factor VIII, and it is possible that the epitope of the light chain with which the inhibitor reacts is partly blocked by the von Willebrand factor.
We conclude that inhibitors may differ in their reactivity with factor VIII molecules contained in clotting factor concentrates, and that there is factor VIII epitope variation between different concentrates. These findings have implications for the selection of concentrates for the treatment of inhibitor patients and the haemostatic effect may be improved if a concentrate giving the lowest inhibitor titre is chosen. Thus, in vitro testing of inhibitor reactivity with a panel of concentrates is recommended when treatment of inhibitor patients with factor VIII concentrates is considered.     

Use of Protein-A column and porcine factor VIII

Extracorporeal immunoadsorption of factor VIII (FVIII) antibodies using Sepharose matrix columns coupled with staphylococcal Protein-A was reported two decades ago. The efficiency of this technique for removing FVIII antibodies of the IgG subtypes was clearly demonstrated. The recent widespread use of a variety of apheresis techniques for the management of a multitude of haematological and oncological conditions has made this technology more accessible and affordable. For the treatment of patients with FVIII inhibitors, the use of porcine FVIII makes it possible to control haemostasis with a therapeutic product for which in vitro testing can help predict the in vivo efficacy. By lowering the level of FVIII inhibitors, immunoadsorption can make the use of pFVIII concentrate possible in situations otherwise untreatable with FVIII preparations. Moreover, lowering the level of FVIII inhibitors by immunoadsorption allows adequate haemostasis to be achieved with much lower doses of FVIII leading to significant saving. Our preliminary data suggest that immunoadsorption combined with the use of pFVIII should be considered early in the treatment plan for controlling haemostasis in patients with FVIII inhibitors.     

Immunoblot analysis shows changes in factor VIII inhibitor chain specificity in factor VIII inhibitor patients over time

We have used immunoblotting of purified factor VIII (FVIII) to determine whether or not changes in FVIII chain specificity occur during the course of an inhibitor. Serial plasma samples from 15 inhibitor patients (13 hemophilic and two spontaneous) were analyzed. Nine of the 15 antibodies, all with epitopes on the 44-kilodalton (Kd) thrombin fragment of the 92-Kd FVIII heavy chain and/or the 72-Kd thrombin fragment of the 80-Kd FVIII light chain, showed no change in FVIII chain specificity. However, six of the inhibitors analyzed showed changes in FVIII fragment specificity. Four inhibitors (three hemophilic and one spontaneous) reactive with 72-Kd thrombin fragment also became reactive with the 44-Kd thrombin fragment after an anamnestic response to FVIII infusion. Another inhibitor with epitopes on both the 54-Kd and 44-Kd thrombin fragments lost most of its reactivity with the 44-Kd fragment but retained its reactivity with the 54-Kd fragment following a FVIII infusion. The inhibitor later regained its 44-Kd-fragment reactivity but lost its 54-Kd-fragment reactivity following treatment with FEIBA, FVIII inhibitor bypassing activity. The last inhibitor studied had an antibody to either the 44-Kd fragment or to both the 44-Kd and 72-Kd fragments during anamnestic responses to FVIII. These data indicate that a FVIII inhibitor patient can potentially produce antibody to multiple areas on the FVIII molecule and that this must be taken into account in the design of specific therapeutic products.     

Development of a factor VIII inhibitor in a newborn haemophiliac

A major problem in the treatment of haemophilia A is the development of inhibitors (antibodies) against factor VIII. We report the case of a newborn male with no family history of haemophilia who developed an intracerebral haemorrhage. On day 10 post-delivery severe haemophilia A was diagnosed and treatment with recombinant FVIII (rFVIII) concentrate was started. Seventy-two hours later the presence of inhibitors was suspected because high doses of rFVIII were required to maintain therapeutic FVIII plasma levels. Days after, the inhibitor was detected. The quick detection of the inhibitor in this newborn haemophiliac allowed us to start the immunotolerance early, without interruption in the administration of rFVIII.     

Variable inactivation of human factor VIII from different sources by human factor VIII inhibitors

The source of human factor VIIII (FVIII) had a marked effect on the inhibitory activity of a panel of eight human FVIII inhibitors. Use of conventional FVIII concentrates gave lower inhibitor titres whereas a monoclonal antibody purified FVIII concentrate gave titres similar to or greater than those with plasma. Addition of phospholipid (PL) protected highly purified FVIII against inhibition. The content of PL-bound FVIII in concentrates may account for the observed differences.     

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.     

Antibodies to factor VIII in plasma of patients with hemophilia A and normal subjects

 Non-neutralizing factor VIII (FVIII) antibodies (FVIII-Ab) in hemophilia A may be associated with an abnormal clinical response to FVIII concentrates. Patients with FVIII inhibitors may develop noncoagulation FVIII-Ab after the induction of immunotolerance. Natural FVIII-Ab may be detected in the plasma of some healthy subjects. The aim of this study was to analyze the presence of FVIII-Ab in the plasma of 53 normal blood donors and 124 patients with hemophilia A (18 patients had a previous history of FVIII inhibitor, but only 12 had inhibitor at the moment this study was performed). FVIIII inhibitor was measured using the Bethesda method. FVIII-Ab were analyzed by a specific ELISA assay using purified FVIII from a monoclonal concentrate and a standard plasma containing 26 Bethesda units (BU) of FVIII inhibitor. Purified FVIII was used to coat wells of a microtiter plate and was incubated with dilutions of plasma to be tested. Bound human IgG FVIII-Ab were detected by incubation with polyclonal sheep anti.human IgG alkaline phosphatase conjugate, and the OD₄₀₅ was quantitated. A linear fit was obtained (by plotting FVIII-Ab positivity [OD 405nm] versus BU titer) when serial dilutions of this standard inhibitor plasma, containing titers of 0.5 BU or higher, were used. Four different levels of FVIII-Ab positivity [OD 405nm] were distinguished in this assay: Negative levels (–) were obtained with dilutions of the standard inhibitor containing <0.5 BU. Mild levels (+) were obtained with dilutions of 0.5–5 BU. Moderate levels (++) were obtained for dilutions ranging from 5–25 BU. Maximum positivity (+++) was obtained for dilutions of titers > 25 BU. FVIII-Ab positivity was detected in eight of the normal subjects (15%): three were found to be moderately positive (++) and five mildly positive (+). No inhibitory activity was detectable when whole plasma was used. All the hemophilic patients with a presence of FVIII inhibitor at the time of the study were found to be positive for FVIII-Ab. In addition, the level of positivity correlated with the corresponding BU. Four of the six patients who had a history of inhibitor were negative and two positive. Twenty additional patients (16.12%) in whom no inhibitory activity was detected were found to be positive for FVIII-Ab: 16 + and four ++. The mean age of patients with FVIII-Ab positivity was significantly higher than that of patients of the FVIII-Ab negative group (p<0.005). In conclusion, FVIII-Ab positivity in patients with hemophilia A was 17.7% higher than the level of positivity detected by an inhibitory assay. We propose that this method for FVIII-Ab analysis could be used for patients with hemophilia A, at least to complement the functional inhibitor assay. FVIII recovery or half-life should be assessed in patients who test positive for FVIII-Ab and who show no evidence of inhibitor. Received: 31 July 1995 / Accepted: 25 January 1996     

Impact of inhibitor epitope profile on the neutralizing effect against plasma-derived and recombinant factor VIII concentrates in vitro

The inhibitory capacity of plasma samples from 24 patients with severe haemophilia A and high-responding inhibitors were evaluated in a concentrate-based assay using two plasma-derived (Haemate and Monoclate-P) and three recombinant (Helixate, Recombinate and ReFacto) factor VIII concentrates and correlated with the corresponding epitope profile. In most, but not all, inhibitor plasmas with a relatively low reactivity against the von Willebrand-containing product Haemate, the main epitopes were located in the FVIII light chain. The reactivities within the group of recombinant products varied in that the reactivity against the B-domain deleted ReFacto was in general higher than that against Recombinate and Helixate. This difference did not correlate with any particular epitope profile and indicates that the B-domain, type of formulation and/or purification procedures may have an impact on the inhibitor reactivity in vitro. The ratio between the inhibitor titres in the concentrate-based assay and the Bethesda assay was dependent on the inhibitor plasma and concentrate used. Taken together, our results show that the reactivity of inhibitor plasmas varies considerably between different FVIII concentrates and that it does not fully correlate with the epitope profile. Potential clinical implications of the observed differences in inhibitor reactivity are discussed.     

Progress in large-scale purification of factor VIII/von Willebrand factor concentrates using ion-exchange chromatography

Background and Objectives We investigated and optimized the parameters of a chromatographic process suitable for industrial scale to obtain a highly purified factor VIII (FVIII)/von Willebrand factor (VWF) concentrate. Materials and Methods Several chromatographic runs were performed on the same production intermediate using different anion-exchange supports. The best matrix was selected and the final product was characterized. Once the chromatographic medium was chosen, the other parameters were evaluated to obtain the highest purified product and to modulate the VWF content in the FVIII/VWF complex. Results Fractogel EMD TMAE was the best support among those tested. It was the only one maintaining good results either with standard or double loading and flow rate conditions with respect to a typical industrial process. The chromatographic recovery of FVIII co-purified with VWF was at least 86% with a specific activity not lower than 140 IU/mg. The FVIII/VWF complex obtained is highly pure and, with the exception of immunoglobulin M (IgM), all investigated contaminant proteins are under the detection limit. Different concentrates characterized by variable FVIII/VWF ratios were purified by varying the chromatographic conditions. Conclusions Several highly purified products, suitable for haemophilia A and von Willebrand disease management, can be obtained, through the same chromatographic process, on an industrial scale.     

Impact of different inhibitor reactivities with commercial factor VIII concentrates on thrombin generation

In order to describe the haemostatic role of a variation in inhibitor reactivity with different factor VIII (FVIII) concentrates, we have compared inhibitor titres against a panel of FVIII concentrates and correlated titre with the capacity to inhibit thrombin generation. Three plasma-derived concentrates were tested in vitro in mixing experiments with inhibitor plasmas from 11 patients with severe haemophilia A: Fanhdi, which contains von Willebrand factor (VWF) with a final ratio of approximately 1:1 (VWF IU per IU FVIII:C); Haemate-P with a ratio of 2.5:1 and Hemofil-M containing only trace amounts of VWF. In addition, the recombinant FVIII concentrate Kogenate Bayer containing no VWF was included. Inhibitor titres and the capacity to generate thrombin were measured. A statistically significant difference in measured titres was found with the highest titres recorded against Hemofil-M. The inhibitor titres needed to inhibit 50% maximum thrombin generation were the lowest for Kogenate Bayer and the highest and similar for Fanhdi and Haemate-P with intermediate titres needed for inhibition of Hemofil-M. In this study, the thrombin generation assay provides additional indications for the role of VWF in the treatment of patients with inhibitors. The VWF-containing concentrates Fanhdi and Haemate-P, added to FVIII-deficient plasma with the presence of inhibitor, generate more thrombin than do the purified concentrates Hemofil-M and Kogenate Bayer.     

In vitro and in vivo characterization of a high-purity, solvent/detergent-treated factor VIII concentrate: evidence for its therapeutic efficacy in von Willebrand's disease

A factor VIII (FVIII) concentrate, virus-inactivated by the solvent/detergent procedure, was studied in vitro. In contrast with most high-purity, virus-inactivated FVIII concentrates, it contains not only high levels of von Willebrand factor (vWF) antigen and ristocetin cofactor activity but also high molecular weight forms of von Willebrand factor. Furthermore, it is able to promote platelet adhesion on collagen in a perfusion system. In vivo studies performed in patients with different types of von Willebrand's disease provided evidence that this concentrate corrects Duke's bleeding time and prevents or stops haemorrhages. Thus, the particular advantages of this FVIII/vWF preparation are safety, low content of contamination proteins, and efficacy in von Willebrand's disease.     

Further evidence for recessive inheritance of von Willebrand disease with abnormal binding of von Willebrand factor to factor VIII.

A new family with a bleeding diathesis and FVIII deficiency secondary to abnormal binding of von Willebrand factor (vWF) to factor VIII (FVIII) is described. Two propositi of this family, an 18-year-old male and a 33-year-old female, both with a history of epistaxis, bruising, bleeding from the gums, epistaxis, hemarthrosis, and hematoma, were analyzed. Also additional members of the same family with no bleeding history were also studied. The propositi showed normal vWF activities, low FVIII activity; one of them had been diagnosed as having hemophilia A and the other was a hemophilia A carrier. Both showed a very poor response to treatment with FVIII concentrates and desmopressin (DDAVP) but a good clinical response to cryoprecipitate. APTT was prolonged and no inhibitory activity was noticeable in their plasmas. Thirty-five units per kilogram body weight of Hemofil M was infused to both propositi and FVIII reached basal level within 60 minutes of the infusion. No FVIII response at all was observed in the female after intravenous DDAVP administration. However, the male who received the infusion of 35 U/kg body weight of Humate-P achieved a normal FVIII level that was maintained for 12 hours. Multimeric analysis of vWF was normal in all the members studied. Von Willebrand factor domain for FVIII binding was assayed in the two propositi and in six other members of the same family by using a non-isotopic and sensitive method, a modification of the one previously described, using the Hemofil M concentrate as exogenous FVIII. The data obtained showed that both propositi had similar binding to that observed by using plasma of a patient with severe von Willebrand disease. Furthermore, five siblings had a decreased binding of vWF to FVIII, when compared with plasma from normal individuals or patients with hemophilia A. We also observed that, for screening purpose, the ratio of bound FVIII/immobilized vWF (at saturation of the anti-vWF and offering of 1 U/ml of exogenous FVIII) distinguished two levels of abnormality (normal range 0.70-1.15, propositi 0.004-0.007, and remaining members affected 0.25-0.42). The most probable explanation is that the propositi are homozygous or double heterozygous, the other five siblings affected being heterozygous for a recessive vWF defect. This more accessible assay presented here may be of help in routine analysis for diagnosing this type of von Willebrand disease, which has important implications for therapy and genetic counseling.     

von Willebrand factor in factor VIII concentrates protects against neutralization by factor VIII antibodies of haemophilia A patients

We investigated the neutralization activity of factor VIII (FVIII) antibodies of 12 haemophilia A patients, acquired during treatment with plasma-derived FVIII concentrates. All plasma samples, drawn in a clinically stable situation before any immunotolerance treatment, contained anti-A2 domain and anti-light-chain FVIII antibodies. In nine patients' plasmas, containing relatively high amounts of FVIII light-chain antibodies (53-96%), a higher neutralization activity was found against recombinant FVIII concentrate (Recombinate) than against plasma-derived von Willebrand factor (vWF)-containing concentrate (Haemoctin SDH). No difference in neutralization of the two concentrates was found in two patients' plasmas with almost equal content of FVIII light- and heavy-chain antibodies, or one plasma with predominantly heavy-chain antibodies. These results suggest that haemophilia A patients with relatively high amounts of FVIII light-chain antibodies in plasma might benefit by infusion of FVIII concentrates containing vWF because vWF appears to have some protective effect on FVIII. This hypothesis should be tested by a clinical study.     

Immune tolerance therapy in paediatric haemophiliacs with factor VIII inhibitors: 14 years follow-up

We report our clinical experience in the immune tolerance (IT) therapy of 21 paediatric haemophiliacs with FVIII inhibitor: high responders (16HR) received initially FVIII twice daily at a dosage of 50–300 U/kg/day, 11/16 received a concomitant treatment with activated prothrombin complex concentrate (100–200 U/kg/day). Low responders (five LR) received 20–100 FVIII U/kg every second or third day. Inhibitor elimination was achieved in 19/21 patients in a median time of 4 months in HR and 1.5 months in LR. The outcome and length of time needed to induce IT was significantly correlated with FVIII exposure between the first inhibitor detection and onset of IT therapy and to interruption of IT therapy. For a rapid elimination of FVIII inhibitors it is important to start continuous administration of high-dose FVIII (≥ 100 FVIII U/kg/day) before repeated exposure to FVIII, in order to prevent rebooster effects, prolongation of elimination time, and to reduce expense.     

von Willebrand factor containing factor VIII concentrates

There are several plasma derived von Wille-brand factors (vWF) containing factor (FVIII) concentrates that can be used in the treatment of von Willebrand disease (vWD). All concentrates are effective in attaining normal postinfusion levels or of FVIII:C but it is difficult to achieve normalization of the bleeding time even with concentrates containing almost all vWF multimers including those of high molecular weight. Haemate P (Centeon) may be considered as the golden standard concentrate available at present. However, the development of more purified vWF concentrates devoid of FVIII:C is the goal for future development.     

Management of spontaneous inhibitors in children with porcine factor VIII

Acquired factor VIII (FVIII) inhibitors are rare, typically occurring in the postpartum period or in the elderly. Their occurrence in childhood is distinctly unusual. Acquired FVIII inhibitors are often life-threatening and refractory to treatment with high doses of human FVIII concentrate. Alternative strategies for control of haemostasis include the use of products with FVIII 'bypassing' activity or porcine FVIII (pFVIII) concentrate if the pFVIII titre is sufficiently low (<10–20 porcine Bethesda Units). Corticosteriods and other immunosuppressive therapies are inconsistently effective in eliminating FVIII inhibitors. Accordingly, acquired FVIII inhibi-tors often require long-term haemostatic management.