Inhibitors in young boys with haemophilia.

The development of an inhibitor antibody to factor VIII (or factor IX) in a child with haemophilia presents a major challenge to the paediatric haematologist. This article provides an overview of the incidence of inhibitor development in early childhood (30-52% in boys with severe haemophilia A), genetic risk factors, detection, high titre, low titre and transient inhibitors, and management. Treatment of patients with inhibitors is time-consuming and expensive. One should make every attempt to ensure that the boy's family has an understanding of inhibitors, treatment options, and just what is being recommended for their child and what this involves. Immune tolerance induction is successful in approximately 85% of boys with factor VIII inhibitors, but in only 40-50% of those with factor IX inhibitors. For treatment of bleeding episodes in children with high-titre (> or = 5 Bethesda Units) inhibitors, therapeutic options include activated prothrombin complex concentrates (APCC), rF VIIa, and (for factor VIII inhibitors) porcine factor VIII. The advantages and disadvantages of each are discussed. Although factor IX inhibitors are far less common (occurring in 2-3% of boys with haemophilia B), approximately 50% are accompanied by the occurrence of anaphylaxis or severe allergic reactions to any factor IX-containing product.     

Effect of recombinant factor VIIa on the hemostatic defect in dogs with hemophilia A, hemophilia B, and von Willebrand disease.

Recombinant factor VIIa (rF.VIIa) is a two-chain procoagulant enzyme (Mr, approximately 50,000) active only when complexed with tissue factor in the extrinsic clotting system. We administered human rF.VIIa to hemophilic and von Willebrand disease (vWD) dogs to determine its hemostatic effectiveness and survival in the circulation. Hemophilia A dogs lacking factor VIII demonstrated an immediate increase in plasma rF. VIIa and prompt stoppage of hemorrhage at bleeding time (BT) sites. In seven studies in two dogs, the range of dose of rF. VIIa was 50-220 micrograms/kg, with an apparent 7- to 11-fold increase in plasma factor VII and a mean recovery in plasma of 34%. The t1/2 was 2.8 +/- 0.5 hr. The BT was normalized except in an animal given the minimum dose. In four studies in two hemophilia B dogs lacking factor IX, BT was normalized. The elevation in plasma factor VII was by a factor of 8-30, with a mean recovery of rF.VIIa in plasma of 44%. In two studies in a homozygous vWD dog lacking von Willebrand factor, which is needed for platelet function, BT was not corrected even though large doses of rF. VIIa were given. The human rF. VIIa protein was immunogenic for dogs. These studies indicate that factor VIIa corrects the hemostatic defect in dogs with hemophilia A and B, diseases primarily of the intrinsic clotting system, but does not correct the hemostatic defect in vWD.     

Use of recombinant factor VIIa in hereditary bleeding disorders

Recombinant factor VIIa is effective as a factor VIII or IX bypassing agent and is relatively safe for the management of bleeding and surgical procedures in patients with factor VIII or IX inhibitors (congenital or acquired hemophilia). It is one of several options in the overall treatment strategy for patients with these difficult conditions. This drug has also been used off label in a limited number of patients with other hereditary bleeding disorders (e.g., factor VII deficiency or antibodies to other clotting factors, and platelet disorders such as Glanzmann thrombasthenia). This paper reviews the proposed mechanisms of action, clinical effectiveness, and safety of rFVIIa for treatment of these disorders and points out areas that require further studies. With expanding indications and more widespread use, thromboembolic complications must be carefully monitored, especially in patients at risk for thromboembolism. The high cost of this drug may be a limiting factor.     

The use of porcine factor VIII concentrate (Hyate:C) in the treatment of patients with inhibitor antibodies to factor VIII. A multicenter US experience

The response to a highly purified concentrate of porcine factor VIII was evaluated in 45 bleeding episodes in 38 patients with high responding inhibitor antibodies to factor VIII. A total of 437 infusions were given. The patients came from 25 hemophilia centers in the United States. The majority had a life- or limb-threatening hemorrhage for which other modalities had not been successful. In 32 of 45 episodes, a good to excellent response was obtained. Adverse reactions were minimal, occurring in 17 treatment episodes, and were mostly treated with antihistamines and/or hydrocortisone. No clear predictor of clinical response to porcine factor VIII concentrate was identified, including pretreatment human and porcine inhibitor levels, percentage of cross-reactivity between the human and porcine antibodies, and the presence of measurable levels of factor VIII after the porcine factor concentrate was given. Anamnesis to porcine factor VIII did occur in some instances. Porcine factor VIII is a valuable modality in the treatment of serious hemorrhages in patients with inhibitors to factor VIII. Its use should be considered early in the course of severe hemorrhage in these patients.     

Current status of hemophilia patients and recombinant coagulation factor concentrates in Japan

The first recombinant factor VIII concentrate was introduced in 1987 to treat hemophilia A patients, and the product was licensed in the United States in 1992. More than 10 years have passed since the recombinant products have been used for treatment of hemophilia A. The new therapeutic options seem to be safe and effective through the gathered experiences. Recently, recombinant factor VIIa concentrate has become available to treat hemophilia patients with inhibitor and factor VII deficiency patients in Europe and also recombinant factor IX for the treatment of hemophilia B has been licensed in the United States and Europe. The usage of recombinant coagulation factors has expanded the routine therapy for hemophilia in many countries. In Japan, the consumption of recombinant factor VIII is increasing year by year, because many patients have started to think that the recombinant technology seems to be safe. Unfortunately, though, the factor VIIa and factor IX products have not been licensed yet in Japan. This article discusses the current status of patients with hemophilia and recombinant coagulation factor products in Japan.     

Current status and future prospects for the prophylactic management of hemophilia patients with inhibitor antibodies

Inhibitor antibodies to factor VIII arise in a substantial minority of patients with hemophilia A treated with replacement therapy; factor IX inhibitors in treated hemophilia B patients are considerably less common. As replacement therapy is not feasible in most such patients, hemostasis can generally only be achieved with “inhibitor bypassing agents”, namely (activated) prothrombin complex concentrates and recombinant factor VIIa. These agents are widely used to treat active bleeding in inhibitor patients but they have been used relatively infrequently as prophylactic agents to prevent bleeding and its consequences, mainly progressive joint damage. This is in contrast to hemophilia patients without inhibitors, in whom prophylactic replacement with concentrates of factor VIII or IX has become widely accepted as the optimal strategy to prevent these adverse outcomes. This review addresses the current experience and evidence and the future prospects regarding prophylaxis in inhibitor patients.     

Recombinant coagulation factor VIIa: from the concept to clinical application in hemophilia treatment in 2000

The development of factor VIII and factor IX concentrates markedly improved the management of hemophilia A and B and made home therapy possible. However, treatment of hemophilic patients with acquired inhibitors remained difficult. The preparation of prothrombin complex concentrates, nonactivated or activated, addressed this difficult clinical problem, but their use was associated with serious side effects. Factor VIIa was found to be a safer treatment modality. Factor VIIa per se is inactive and needs tissue factor (TF) to become biologically active. TF serves as the receptor for factor VIIa. TF is expressed from vessel walls only upon injury. Treatment of inhibitor patients with plasma-derived factor VII was found to be successful. This led to the development of recombinant factor VIIa, which was also found to be successful in managing hemophilia patients with inhibitors. Up to this point, large numbers of patients have been treated and few serious side effects have been noted. Because of its unique effects on the hemostasis system, recombinant factor VIIa will be useful for other indications as well, including patients with congenital factor VII deficiency, patients with bleeding and liver function impairment, patients with quantitative and qualitative platelet defects, and individuals who have sustained multiple trauma. The development of recombinant factor VII is reviewed in detail.     

Successful treatment of high titer inhibitors in mild hemophilia A with avoidance of factor VIII and immunosuppressive therapy.

We describe two patients with mild hemophilia A (MHA) who developed high titer inhibitor (HTI) following intensive recombinant factor VIII (rFVIII) concentrate replacement for surgery and trauma. Intranasal desmopressin was instituted shortly following immunosuppressive therapy (IST) and activated prothrombin complex concentrate (APCC) in one case, and following APCC alone in the second case. Avoidance of factor VIII (FVIII) coupled with intranasal desmopressin prophylaxis three times a week resulted in undetectable inhibitor levels. Both patients have had no further bleeding episodes and have been maintained on desmopressin prophylaxis prior to activity for the past 2 to 3 years. Recombinant factor VIIa (rFVIIa) was used successfully prior to a second surgery in one patient without complication.     

The use of continuous infusion of factor concentrates in the treatment of hemophilia

Bolus infusion of clotting factor concentrates remains the most common approach to the treatment or prevention of bleeding in patients with hemophilia. Although successful use of continuous infusion of such concentrates has been reported by several groups, this alternative treatment method has not achieved widespread popularity. We report here our experience in one hemophilia center with the use of continuous infusion of factor VIII and factor IX concentrates in 13 patients, 11 with hemophilia A, and 2 with hemophilia B. All patients were treated successfully for bleeding episodes (e.g., hemarthroses, intracranial, or gastrointestinal bleeding) or for surgical procedures (appendectomy, thoracotomy, etc.). Three patients with low titer factor VIII inhibitors were treated successfully with constant infusion therapy, requiring a mean dose of factor VIII concentrate 2.3 fold (8.20 u/kg/h) higher than that of the patients without inhibitors (3.63 u/kg/h) to maintain a circulating plasma level of factor VIII of 1 u/ml. The use of constant infusion of clotting factor concentrates is safe, efficacious, and more convenient than bolus therapy of factor concentrates and should be considered for hospitalized hemophilia patients requiring replacement therapy.     

Porcine factor VIII provides clinical benefit to patients with high levels of inhibitors to human and porcine factor VIII

The development of an inhibitor against Factor VIII is an important complication of haemophilia and occurs in approximately 31% of patients [1]. Despite various approaches to their management, the presence of these inhibitors remains a major cause of morbidity and mortality. Inhibitors may be low level [<5 Bethesda Units (BU)] or high level [>10 BU]. Low-level inhibitors usually remain low and do not respond to administered factor VIII with a rise of the inhibitor titre; high-level inhibitors, in contrast, are characterized by a rapid rise in titre following treatment with factor VIII. Modalities of treatment of acute bleeding episodes in patients with inhibitors include 'overcoming' the inhibitor with very large doses of factor VIII, 'bypassing' the inhibitor blockade with products such as activated prothrombin complex concentrates or recombinant factor VIIa, 'removing' the inhibitor by plasmapheresis or immunoabsorption and 'repressing' it with immunosuppressive drugs and immune tolerance induction. An alternative approach is to use a porcine factor VIII concentrate which does not cross-react with the human factor VIII inhibitor. Following treatment with porcine factor VIII, functional factor VIII can be detected and the therapeutic levels correlate with cessation of bleeding. The use of porcine factor VIII may, however, result in the development of antiporcine factor VIII antibodies, limiting its use. Experience in patients with high-titre inhibitors indicates that porcine factor VIII therapy could be used in the presence of factor VIII inhibitors [2-11], including inhibitors to porcine factor VIII [5,7], and that haemostasis may be obtained in the absence of detectable levels of circulating factor VIII [7,11].     

Immunoadsorption for coagulation factor inhibitors: a retrospective critical appraisal of 10 consecutive cases from a single institution

Immunoadsorption is occasionally used as an adjuvant measure in the treatment of subjects with coagulation factor inhibitors. We reviewed our recent 3-year period experience with this procedure in 10 subjects. Immunoadsorption was used in the context of an immune tolerance protocol for 3 subjects with severe congenital deficiency in factor VIII, IX, and XIII; it was effective in lowering the level of inhibitor but immune tolerance was not achieved. It allowed successful use of porcine factor VIII in 4 cases of acquired hemophilia and in one case of inhibitor in mild hemophilia A. This therapeutic approach seems to be more useful in acquired hemophilia than in severe congenital factor deficiencies with inhibitors.     

Experience with highly purified porcine factor VIII in a patient with haemophilia A and a factor VIII inhibitor

Highly purified porcine factor VIII has been advocated for the treatment of bleeding episodes in patients with haemophilia who have inhibitors to factor VIII. This approach has been successful in a patient with an intermediate potency inhibitor showing little cross-reactivity to porcine material. As in some other reported cases, a severe allergic reaction occurred on one occasion but did not preclude the subsequent use of the porcine concentrate in carefully controlled conditions.     

The use of recombinant factor VIIa in the treatment of bleeding disorders

Recombinant factor VIIa was initially developed for the treatment of hemorrhagic episodes in hemophilic patients with inhibitors to factors VIII and IX. After its introduction, it has also been used "off-label" to enhance hemostasis in nonhemophilic patients who experience bleeding episodes not responsive to conventional therapy. Evidence so far indicates that the use of factor VIIa in hemophilic patients with inhibitors is both safe and effective. Anecdotal reports also suggest that the product is safe and effective in controlling bleeding in nonhemophilic patients. However, its use in these conditions has not been approved by the FDA, and conclusive evidence of its effectiveness from controlled clinical trials is not yet available. Several questions pertaining to the use of factor VIIa require further investigation, including the mechanism of action; the optimal dose; definitive indications; ultimate safety; and laboratory tests for monitoring therapy.     

Immune tolerance induction for patients with severe hemophilia A: a critical literature review

The development of inhibitors that neutralize the function of clotting factor VIII (FVIII) is currently the most challenging complication associated with the treatment of hemophilia A as it increases the disease-related morbidity and mortality. Immune tolerance induction (ITI) is the only documented strategy to eradicate persistent inhibitors in severe hemophilia A patients. Several studies have been conducted so far to identify patient- and treatment-related factors associated with greater ITI success. The currently available literature on ITI in hemophilia A will be critically reviewed in this article. In particular, we will focus on the role of the type of FVIII product on ITI outcome by analyzing the clinical and experimental data.     

Determinants of plasma factor VIIa levels in humans

Several enzymes can activate factor VII in vitro, but the protease responsible for generating factor VIIa in vivo has not been determined. Using recombinant tissue factor that has undergone a COOH-terminal truncation, a sensitive functional assay has been established for measuring plasma factor VIIa levels. To evaluate the mechanism responsible for the generation of factor VIIa in vivo, we measured the levels of this enzyme after administering purified concentrates of factor IX and factor VIII to patients with severe deficiencies of these clotting factors. In patients with hemophilia B, factor VIIa levels were initially reduced to 0.5 +/- 0.1 ng/mL and gradually increased to normal after infusing 100 U/kg of body weight (BW) of factor IX. Despite these increases, there were no significant changes in the generation of factor Xa or thrombin. In patients with hemophilia A, only a slight reduction in factor VIIa levels (2.5 +/- 1.3 ng/mL) was observed as compared with controls (3.3 +/- 1.1 ng/mL) and no significant changes were observed after factor VIII levels were normalized. The administration of recombinant factor VIIa (10 micrograms/kg BW) to patients with factor VII deficiency increased the mean circulating level of the enzyme to 118 ng/mL, but this only resulted in normalization of the levels of the activation peptides of factor IX and factor X. The above data indicate that factor IXa is primarily responsible for the basal levels of free factor VIIa generated in vivo (ie, in the absence of thrombosis or provocative stimuli) and that changes in the plasma concentrations of free factor VIIa in the blood do not necessarily lead to alterations in the extent of factor X activation.     

Cost effectiveness of prophylactic treatment with activated prothrombin complex concentrate in a patient with inhibitor-positive hemophilia A

Patients with hemophilia and high titers of inhibitors are hard to treat during bleeding events and consequently are more likely to incur high treatment costs and to experience deterioration in quality of life. We report here the case of a boy with hemophilia A and high titers of inhibitors who responded well to prophylactic activated prothrombin complex concentrate (APCC) treatment. Previously, he had to be hospitalized frequently because of painful bleeding of target joints of the knee and ankle. At the age of 4 years and 3 months, APCC prophylaxis at a dose of 60 U/kg, three times a week, was initiated together with on-demand therapy with recombinant factor VIIa. This reduced the frequency and severity of bleeding and ended the need for hospitalization. This, together with a decreased requirement for bypass agents, APCC treatment significantly reduced the cost of treatment for this patient.     

Inhibitors in factor IX deficiency a report of the ISTH-SSC international FIX inhibitor registry (1997–2006)

Summary.  Haemophilia B is an X-linked disorder resulting in coagulation factor IX deficiency. Patients with severe deficiency (<1% factor IX activity) may have significant bleeding complications similar to patients with haemophilia A or factor VIII deficiency. The development of inhibitory antibodies to the missing coagulation factor is a major complication in patients with haemophilia. While the incidence of inhibitors in patients with haemophilia A is higher than that in haemophilia B, the occurrence of allergic and or anaphylactic reactions with the development of inhibitors is unique to haemophilia B patients. Since haemophilia B is a rare bleeding disorder and the incidence of inhibitors is an even rarer entity, a registry was established by Dr Indira Warrier under the auspices of the FVIII/FIX subcommittee of the International Society of Thrombosis and Haemostasis, to gather information on the occurrence and characteristics of patients with inhibitors and also the incidence of allergic and anaphylactic reactions in this group of patients. This is the first report from this registry and helps us to gather some insight on haemophilia B patients with inhibitors and complications related to inhibitor development and difficulties with immune tolerance.     

Low-dose activated factor IX complex concentrates (FEIBAR) for post-operative haemostasis in a patient with high responding factor VIII inhibitors

Replacement therapy in patients with severe haemophilia A is associated with the development of inhibitory antibodies in about 15% [1,2]. The presence of inhibitors of factor VIII greatly complicates and compromises the treatment of these patients because of the lack of any completely satisfactory product to treat them. Haemostatic management for surgery in patients with inhibitors is very difficult. A product frequently used to treat bleeding episodes in such patients is prothrombin complex concentrate (PCC) [3] or its activated derivative (APCC) [4]. Activated recombinant human factor VII is another option [5]. For both these modalities of treatment, there are no laboratory tests that can be used to monitor clinical efficacy [5, 6]. Porcine factor VII is therefore the preferred product for surgery in patients with high-responding factor VIII inhibitors [7]. Unfortunately, none of these products are readily available in most developing countries, including India.
We report the management of a patient with high-responding factor VIII inhibitor using low doses of FEIBA^R (Immuno, Austria) in the post-operative period.     

Ischemic stroke after recombinant factor VIIa treatment in acquired hemophilia A patient

Acquired hemophilia is a rare, life-threatening coagulopathy in adults caused by the development of autoantibodies against factor VIII. Bypass agents such as recombinant factor VIIa (rFVIIa) are usually preferred for bleeding control; however, thromboembolic complications may occur. We report here a case that presented with extensive cutaneous and mucosal bleedings due to factor VIII inhibitors and was treated successfully with rFVIIa and steroid therapy, but was complicated with a life-threatening thromboembolic attack during follow-up.     

Aptamer ARC19499 mediates a procoagulant hemostatic effect by inhibiting tissue factor pathway inhibitor

Hemophilia A and B are caused by deficiencies in coagulation factor VIII (FVIII) and factor IX, respectively, resulting in deficient blood coagulation via the intrinsic pathway. The extrinsic coagulation pathway, mediated by factor VIIa and tissue factor (TF), remains intact but is negatively regulated by tissue factor pathway inhibitor (TFPI), which inhibits both factor VIIa and its product, factor Xa. This inhibition limits clot initiation via the extrinsic pathway, whereas factor deficiency in hemophilia limits clot propagation via the intrinsic pathway. ARC19499 is an aptamer that inhibits TFPI, thereby enabling clot initiation and propagation via the extrinsic pathway. The core aptamer binds tightly and specifically to TFPI. ARC19499 blocks TFPI inhibition of both factor Xa and the TF/factor VIIa complex. ARC19499 corrects thrombin generation in hemophilia A and B plasma and restores clotting in FVIII-neutralized whole blood. In the present study, using a monkey model of hemophilia, FVIII neutralization resulted in prolonged clotting times as measured by thromboelastography and prolonged saphenous-vein bleeding times, which are consistent with FVIII deficiency. ARC19499 restored thromboelastography clotting times to baseline levels and corrected bleeding times. These results demonstrate that ARC19499 inhibition of TFPI may be an effective alternative to current treatments of bleeding associated with hemophilia.