Haemophilia B: current pharmacotherapy and future directions

Introduction: Hemophilia B is a rare hereditary hemorrhagic disorder characterized by deficiency of the clotting factor IX (FIX). Hemophilia B patients experience mild to severe bleeding complications according to the degree of FIX defect. Nowadays, the most challenging complication of individuals with hemophilia B is the development of alloantibodies, which render the standard replacement therapy with FIX concentrates ineffective, exposing them to a significantly increased morbidity and mortality.

Areas covered: This review summarizes the most important events leading to the development of the current FIX products available for the treatment of hemophilia B patients. In addition, it focuses on the more recent advances in the production of new FIX molecules aimed at improving the clinical management of such patients.

Expert opinion: Although the availability of plasma-derived FIX concentrates has greatly improved the clinical management of hemophilia B patients, the introduction of FIX products using recombinant DNA technology has represented the most significant therapeutic progress in hemophilia B therapy, ensuring an advanced level of safety. The development of rFIX products with extended half lives will further improve the therapeutic armamentarium for hemophilia B patients.     

Treatment strategies in children with hemophilia

Hemophilia is an inherited bleeding disorder caused by quantitative or qualitative defects in the synthesis of factor VIII (FVIII) or factor IX (FIX). Clinically, it is divided into severe, moderate and mild disease depending on the levels of FVIII or FIX in the blood. The bleeding tendency is most pronounced and can start at a very young age in severe hemophilia, which is characterized by repeated hemorrhage into the joints and muscles. Without treatment, these episodes lead to severe arthropathy, and there is also a high risk of lethal cerebral hemorrhage. The treatment of bleeding symptoms requires the correction of the coagulation defect. Factor concentrates have been available for 30 years, initially with the development of cryoprecipitate, subsequently with increasingly purified plasma-derived forms, and ultimately with recombinant clotting factor concentrates. The advantage of this highly effective therapy has been subdued by the outbreak of HIV and Hepatitis C infections in patients with hemophilia treated with factor concentrates which did not have adequate viral inactivation steps in the purification process. Plasma-derived and recombinant factor concentrates are today considered to have a good safety profile, but are only available for a small group of hemophilia patients worldwide. A multidisciplinary team approach is important for early diagnosis, communication with the patient and parents, and to tailor the best treatment possible with the amount of clotting factor concentrates available. The main goal of hemophilia treatment is to prevent bleeding symptoms and allow normal integration in social life. In patients with severe hemophilia, this can best be achieved by early home treatment and primary prophylaxis. Future developments in gene therapy may transform severe hemophilia to a mild form, with no need for regular injections of clotting factor concentrates.     

Recent advances in the development of coagulation factors and procoagulants for the treatment of hemophilia

Hemophilia is a family of rare bleeding disorders. The two primary types, hemophilia A and hemophilia B, are caused by recessive X-chromosome linked mutations that result in deficiency of coagulation factor VIII (FVIII) or factor IX (FIX), respectively. Clinically, hemophilia is manifested by spontaneous bleeding, particularly into the joints (haemarthrosis) and soft tissue, and excessive bleeding following trauma or surgery. The total overall number of hemophilia patients worldwide is approximately 400,000, however only about 100,000 of these individuals are treated. The first treatment of hemophilia was initiated when it was determined that the clotting deficiency could be corrected by a plasma fraction taken from normal blood. The discovery of factor VIII enrichment by cryoprecipitation of plasma opened a new era of therapy which eventually led to the production of factor concentrates and the subsequent development of highly purified forms of plasma factors. The most significant improvements have been the availability of recombinant forms of factors VIII and IX. Unfortunately, recombinant factors still retain some of the limitations of plasma concentrates. These limitations include development of antibody responses in patients and the relatively short half-life of the molecules requiring frequent injection to maintain effective concentration. Treatment beyond replacement of native factors has been tried. They include the development of modified factor VIII and IX molecules with improved potency, stability and circulating half-life and enhancement of a prothrombotic responses and/or stabilization of coagulation factors via inhibition of key negative regulatory pathways. These approaches will be reviewed in this commentary.     

The safety of pharmacologic options for the treatment of persons with hemophilia

ABSTRACT

Introduction: The mainstay of treatment of hemophilia A and B is the replacement of the congenitally deficient coagulation factor through the intravenous infusion of specific concentrates (factor VIII, FVIII, in hemophilia A; factor IX, FIX, in hemophilia B). Several commercial brands of FVIII or FIX products extracted from human plasma or engineered using recombinant DNA technology are available.

Areas covered: We analyze the safety aspects of plasma-derived and recombinant FVIII and FIX products licensed in Europe, focusing on their pathogen safety and inhibitor and thrombosis risks. The safety aspects of bypassing agents (i.e., activated prothrombin complex concentrates and recombinant activated factor VII) used for treatment of bleeding episodes in inhibitor patients will be also briefly discussed.

Expert opinion: The analysis of the published literature documents the high degree of safety from pathogen risk for both plasma-derived and recombinant products available for hemophilia treatment. The main threat to factor concentrate safety is represented by the development of neutralizing alloantibodies against the infused coagulation factor, which in hemophilia A seem to occur more frequently following the administration of recombinant than plasma-derived FVIII products. Great expectations are placed on newer products, particularly on those based upon mechanisms of action other than FVIII replacement.     

Emerging drugs for the treatment of hemophilia A and B

Introduction: Replacement therapy with clotting factor concentrates is the most appropriate and effective way to treat bleedings of Hemophilia A&B to prevent chronic arthropathy. Unfortunately, the short half-life (HL) of FVIII/IX concentrates obliges the patients to receive frequent infusions, a big concern for children. The development of inhibitors in about 30–45% of hemophilia A and in 3–5% of hemophilia B patient is the major adverse event of replacement therapy.

Areas covered: In the last few years, new rFIX have been developed with HL. New rFVIII concentrates are displaying small increase of PK characteristics. The new bio-engineering methods allowed the production of molecules fused with Fc fragment of IgG or Albumin or linked to PEG. A new approach to improve hemostasis is represented by Mab against TFPI and small RNA interfering with Antithrombin synthesis. Another innovative drug seems to be the new bi-specific antibody which mimics FVIII function in linking FXa and FX to tenase production.

Expert opinion: The emerging drugs for hemophilia treatment seem to be very promising. The extended half-life will improve the adherence of patients to therapy. Accurate post-marketing surveillance studies will be necessary to check the efficacy, safety and immunogenicity of these new molecules.     

Pharmacokinetic drug evaluation of albutrepenonacog alfa (CSL654) for the treatment of hemophilia

Introduction: Replacement therapy for FVIII/IX in hemophilia A/B is more than 50 years old following the discovery of cryoprecipitate by Judith Pool in 1964. On-demand therapy and prophylaxis to treat or prevent bleedings is very demanding owing to the short half-life (HL) of factor concentrates (no more than 12–14 h for FVIII or 16–18 h for FIX). Patients are very eager to prolong the intervals between bolus. The enhanced HL of long-acting recombinant FIX (rFIX) concentrates seems to fulfill this expectance.

Areas covered: Great improvements have been achieved in the bio-engineering of new rFIX concentrates. Production, formulation, pharmacokinetics, pharmacodynamics, efficacy and tolerability of albutrepenonacog alfa (rIX-FP, trade name Idelvion) will be addressed. rIX-FP is produced by expression of genetically linked FIX and albumin in Chinese Hamster Ovary cells. rIX-FP exhibits a long HL, low clearance and small volume of distribution.

Expert opinion: There is no doubt that rIX-FP, as well as other long-acting rFIX concentrates, will facilitate and improve the adherence to therapy of younger hemophilia patients, toddlers and children. Efficacy, safety and immunogenicity of rIX-FP must be assessed not only during the regulatory clinical trials but also by post-marketing surveillance.     

Conformational comparability of factor IX-Fc fusion protein, factor IX, and purified Fc fragment in the absence and presence of calcium

A long lasting recombinant factor IX -Fc fusion protein (rFIX-Fc) is being developed for the treatment of hemophilia B and is currently in late stage clinical investigation. By limiting injection frequency and maintaining efficacy, rFIX-Fc shows promise as a new therapeutic option for hemophilia B patients. However, before gaining regulatory approval, rFIX-Fc must undergo rigorous analytical and biological testing, in addition to clinical trials. Included in this testing is the need to understand this protein's higher-order structure and dynamics. In this study, we investigated and compared the biophysical properties of rFIX-Fc, rFIX, and Fc using hydrogen/deuterium exchange mass spectrometry and differential scanning calorimetry. Within the limits of these techniques, our results show that structural comparability exists between rFIX and the FIX region of rFIX-Fc. In addition, changes in the structure and dynamics of both proteins, in response to calcium binding, a requirement for FIX function, are also highly comparable. In the case of Fc and Fc region of rFIX-Fc, conformational comparability is also established. These biophysical results further support the conclusion that fusing an immunoglobulin gamma 1 Fc to rFIX does not significantly alter the higher-order structure of FIX or Fc, Ca binding to FIX, or Fc functionality.     

Safety of recombinant coagulation factors in treating hemophilia

Introduction: During the last decade, new FVIII/IX concentrates have been developed for the treatment of patients affected by hemophilia A/B. Significant progress has been achieved regarding their half-life, but the old issue of immunogenicity and new concerns about safety need to be addressed.

Areas covered: After the implementation of virucidal methods, both plasma-derived and recombinant clotting factor concentrates achieved a very safe profile. The development of anti-FVIII antibodies is the major adverse event of replacement therapy with both FVIII concentrates. Furthermore, the new extended half-life concentrates, protein fused or pegylated, raised some concerns about their side effects.

Expert Opinion: The treatment of hemophilia A with inhibitors by induction of immunotolerance and using by-passing concentrates, improved the quality of life of patients but did not allow them to have a life expectancy like that of patients without inhibitors. The new humanized monoclonal antibody (MAb) ACE910, mimicking FVIII function, seems to be able to reduce the bleedings of hemophilia A patients with inhibitors. The post-marketing surveillance will clarify if the adverse events observed during the phase III clinical trials and compassionate use were due to the association with a Prothrombin activated complex concentrate or to the prothrombotic effect of the drug itself.     

State of care for hemophilia in pediatric patients

On demand treatment of bleeding episodes is still the main approach to hemophilia care of patients of any age. Prompt infusion of coagulation factor concentrate in the home setting allows treatment of hemorrhages at early onset, reducing the incidence of complications and improving the quality of life. Nevertheless, the technological evolution and progressive improvement in the safety of therapeutic products have changed the management of the disease, particularly in children. The current availability of safer concentrates has drastically reduced the risk of transmission of blood-borne infections. Innovative approaches, such as early primary prophylaxis and immune tolerance induction, have become feasible and their introduction represents a major advance in the achievement of the main therapeutic goals: control of the bleeding diathesis and elimination of inhibitors. Prophylactic regimens have been shown to be effective in preventing the occurrence not only of joint bleeding but also of arthropathy when started early in children with severe hemophilia. Inhibitor development still represents the main complication of hemophilia treatment, making concentrate administration ineffective. Immune tolerance induction by daily infusion of coagulation factor concentrate was shown to eradicate the inhibitors in 63 to 83% of patients. These intensive treatment regimens are administered at home to very young children and create the problem of adequate venous access. Subcutaneous venous ports have been used in patients with hemophilia if peripheral veins could not be frequently accessed; however, the risk of infection is an important limit to their use.     

Therapeutic approaches for haemophilia

The life-long episodic bleeding associated with inherited deficiencies of blood coagulation Factor VIII (FVIII) or Factor IX (FIX) can be well controlled with periodic iv. injections of FVIII or FIX concentrates. Either concentrate can be isolated from large human pools (i.e., plasma-derived FVIII or FIX concentrate) or from culture supernatants of recombinant cells engineered to secrete FVIII or FIX. The validated viral inactivation strategies used by manufacturers of FVIII and FIX concentrates have essentially eliminated the transmission of hepatitis B, hepatitis C and HIV viruses. The low yields and inherent instability of FVIII (and FVIIIa in particular) and the additional costs of viral inactivation methods make the annual cost/patient for prophylaxis and treatment of haemophilia very expensive. Several strategies have been adopted and proposed to improve yields of FVIII. These include: deletion of portions of FVIII which are not associated with function; mutations to prevent inactivation of FVIII by protease degradation; and synthesis of FVIII fragments to replace portions deleted in some FVIII deficient patients. An approach to improve FIX replacement involves the production of more coagulatively active FIX mutants. Another promising approach in both FVIII and FIX replacement is gene therapy. Two major issues that will have to be critically addressed before gene therapy for haemophilia can become widespread are whether the procedures will be well-tolerated in patients with significant liver impairment (due to previous exposure to hepatitis viruses) and whether consistent long-term delivery of the transgenes can be achieved.     

The use of pharmacokinetics in dose individualization of factor VIII in the treatment of hemophilia A

Introduction: Hemophilia A is a bleeding disorder resulting from a lack of clotting factor VIII (FVIII), and treatment typically consists of prophylactic replacement of the deficient factor. However, high between subject variability precludes the development of a ‘one size fits all’ dosing strategy and necessitates an individualized approach. We sought to summarize the data on the pharmacokinetics of FVIII available as a basis for the development of population pharmacokinetic models to be used in dose tailoring.

Areas covered: We reviewed the pharmacokinetics of FVIII as used for the treatment of hemophilia A, with a focus on the variability observed between patients and the application of pharmacokinetic methods to dose individualization. We also explored the covariates affecting pharmacokinetic parameters, the differences between plasma-derived and recombinant FVIII and the development of extended half-life products.

Expert opinion: The pharmacokinetics of factor VIII in patients with hemophilia shows a high interpatient variability, and is affected by age, weight, level of von Willebrand factor, and blood group. A population approach to estimating individual pharmacokinetics is likely to provide the most successful strategy to tailor factor concentrate dosing to the individual needs and to ensure optimal patient outcomes, while also improving the cost-effectiveness of prophylactic replacement therapy.     

血友病A的基因治疗

血友病A是一种X-连锁隐性遗传病,在男性中的发病率约为（1～2）/10000。血友病A的临床症状主要是自发性关节、软组织或其他组织的出血、血肿,常可致残,甚至危及生命。其致病机制是由于编码凝血因子Ⅷ的基因先天性异常而导致的凝血因子Ⅷ缺乏或功能缺陷。血友病A是基因治疗的首选疾病之一。本文就血友病A基因治疗中所采用的载体和靶细胞作一综述。     

The availability of new drugs for hemophilia treatment

ABSTRACT

Introduction

A number of new FVIII/IX concentrates enriched the portfolio of products available for the treatment of hemophilia A/B patients. Due to the large inter-patient variability, accurate tailoring of the therapy became essential to improve patients’ adherence, clinical outcomes, and cost/effectiveness ratio. Recently, non-replacement therapies have taken the limelight and succeeded in decreasing the bleedings of patients.     

FVIII at the crossroad of coagulation,bone and immune biology: Emerging evidence of biological activities beyond hemostasis

Hemophilia A is an X-linked hereditary disorder that results from deficient coagulation factor VIII (FVIII) activity, leading to spontaneous bleeding episodes, particularly in joints and muscles. FVIII deficiency has been associated with altered bone remodeling, dysregulated macrophage polarization, and inflammatory processes that are associated with the neoformation of abnormal blood vessels. Treatment based on FVIII replacement can lead to the development of inhibitors that render FVIII concentrate infusion ineffective. In this context, hemophilia has entered a new therapeutic era with the development of new drugs, such as emicizumab, that seek to restore the hemostatic balance by bypassing pathologically acquired antibodies. We discuss the potential extrahemostatic functions of FVIII that may be crucial for defining future therapies in hemophilia.     

Drug therapy reviews: clinical use of hemostatic agents.

Systemic hemostatic agents are reviewed. Among the agents discussed are vitamin K preparations (phytonadione, menadione, menadione sodium bisulfite, menadiol sodium diphosphate); and blood products (whole blood, plasma, cryoprecipitate, factor VIII concentrates, factor IX concentrates and fibrinogen concentrates). Normal and abnormal hemostasis and fibrinolysis are discussed, as is the general management of systemic hemostatic defects. Specific disorders covered are clotting factor deficiencies, hemophilia A, factor VIII inhibitors, von Willebrand disease, hemophilia B (Christmas disease), other congenital coagulation disorders, acquired deficiency of factors II, VII, IX and X, and defibrination syndrome.     

Pharmacokinetics of coagulation factors: clinical relevance for patients with haemophilia.

Haemophilia is a recessively inherited coagulation disorder, in which an X-chromosome mutation causes a deficiency of either coagulation factor VIII (FVIII) in haemophilia A, or factor IX (FIX) in haemophilia B. Intravenous administration of FVIII or FIX can be used to control a bleeding episode, to provide haemostasis during surgery or for long term prophylaxis of bleeding. In special cases, activated factor VII (FVIIa) may be used instead of FVIII or FIX. The aim of this work is to review the pharmacokinetics of FVIII, FIX and FVIIa and to give an outline of the use of pharmacokinetics to optimise the treatment of patients with haemophilia. The pharmacokinetics of FVIII are well characterised. The systemic clearance (CL) of FVIII is largely determined by the plasma level of von Willebrand factor (vWF), which protects FVIII from degradation. Typical average CL in patients with normal vWF levels is 3 ml/h/kg, with an apparent volume of distribution at steady state (Vss) that slightly exceeds the plasma volume of the patient, and the average elimination half-life (t1/2) is around 14 hours. There are still some discrepancies in the literature on the pharmacokinetics of FIX. The average CL of plasma-derived FIX seems to be 4 ml/h/kg, the Vss is 3 to 4 times the plasma volume and the elimination t1/2 often exceeds 30 hours. FVIIa has a much higher CL (average of 33 ml/h/kg), and a short terminal t1/2 (at 2 to 3 hours). The Vss is 2 to 3 times the plasma volume. Since the therapeutic levels of coagulation factors are well defined in most clinical situations, applied pharmacokinetics is an excellent tool to optimise therapy. Individual tailoring of administration in prophylaxis has been shown to considerably increase the cost effectiveness of the treatment. Dosage regimens for the treatment of bleeding episodes or for haemostasis during surgery are also designed using pharmacokinetic data, and the advantages of using a constant infusion instead of repeated bolus doses have been explored. The influence of antibodies (inhibitors) on the pharmacokinetics of FVIII and FIX is in part understood, and the doses of coagulation factor needed to treat a patient can tentatively be calculated from the antibody titre. In conclusion, therapeutic monitoring of coagulation factor levels and the use of clinical pharmacokinetics to aid therapy are well established in the treatment of patients with haemophilia.     

Chimeric proteins comprising the constant region of immunoglobulins for treating hemophilia B (WO2005001025)

The application (WO2005001025) details recombinant fusion proteins attached to the constant region of heavy chains of immunoglobulins. They are found to be particularly useful for the treatment of hemostatic disorders, such as hemophilia B. It aims at engineering chimeric proteins comprising of a single molecule of human factor IX (FIX) and the constant region (Fc domain) of one or two heavy chain(s) of human IgG (rFIXFc). cDNA for rFIXFc was generated by a PCR. rFIXFc protein was isolated and purified from stably transfected mammalian cells. The concentration and clotting activity of rFIXFc were assessed in mice, rats, monkeys, and FIX-deficient mice and dogs, after intravenous administration. The half-life of rFIXFc activity is prolonged by three to fourfold, compared with rFIX, when administered intravenously in all animals. The generation of chimeric proteins, comprised of FIX fused to the Fc domain of IgG, extends the clotting activity of the recombinant molecule. rFIXFc represents a promising candidate for the treatment of patients with hemophilia B. The application claims the methods of making recombinant chimeric proteins comprising of one biologically active molecule fused to the Fc region of the heavy chain(s) of immunoglobulins and their use for therapy.     

Chimeric proteins comprising the constant region of immunoglobulins for treating hemophilia B (WO2005001025)

The application (WO2005001025) details recombinant fusion proteins attached to the constant region of heavy chains of immunoglobulins. They are found to be particularly useful for the treatment of hemostatic disorders, such as hemophilia B. It aims at engineering chimeric proteins comprising of a single molecule of human factor IX (FIX) and the constant region (Fc domain) of one or two heavy chain(s) of human IgG (rFIXFc). cDNA for rFIXFc was generated by a PCR. rFIXFc protein was isolated and purified from stably transfected mammalian cells. The concentration and clotting activity of rFIXFc were assessed in mice, rats, monkeys, and FIX-deficient mice and dogs, after intravenous administration. The half-life of rFIXFc activity is prolonged by three to fourfold, compared with rFIX, when administered intravenously in all animals. The generation of chimeric proteins, comprised of FIX fused to the Fc domain of IgG, extends the clotting activity of the recombinant molecule. rFIXFc represents a promising candidate for the treatment of patients with hemophilia B. The application claims the methods of making recombinant chimeric proteins comprising of one biologically active molecule fused to the Fc region of the heavy chain(s) of immunoglobulins and their use for therapy.     

Clinical gene therapy - first international conference. 24-26 January 2002, Groningen, the Netherlands

The first International Conference on Clinical Gene Therapy focused primarily on gene therapy for cardiovascular disorders, genetic diseases (hemophilia, cystic fibrosis) and cancer, with particular emphasis on clinical trials and advanced preclinical studies. Recent improvements in vector technologies led to the first demonstration that gene therapy could cure a disease in a clinically relevant animal model of hemophilia. This significant progress at the preclinical level, using both viral and non-viral vectors, paved the way for phase I clinical trials in patients suffering from hemophilia A. The first report on hemophilia A gene therapy using a non-viral ex vivo approach was encouraging and revealed modest improvements in clinical endpoints. The status of clinical gene therapy for the treatment of peripheral limb and myocardial ischemia by therapeutic angiogenesis was highlighted as showing an apparent increase in collateral development and reduced limb or myocardial ischemia in some patients. Gene therapy for cystic fibrosis turned out to be a much tougher nut to crack than initially assumed, and the hopes for, and hurdles faced by, gene therapy approaches for this disease were discussed. Phase III clinical trials using retroviral-based suicide gene therapy for cancer revealed no significant therapeutic benefit in patients suffering from glioblastoma multiforme. Nevertheless, new and promising approaches for cancer gene therapy are being developed that rely on the use of targetable vectors and conditionally replicating vectors that replicate specifically in cancer cells; this may overcome some of the bottlenecks of cancer gene therapy by improving therapeutic efficacy. Although few diseases have been treated effectively by gene therapy so far, the stage appears set for new and significant advances in clinical trials.     

Efficacy and safety of a recombinant factor VIII produced from a human cell line (simoctocog alfa)

Introduction: The development of inhibitors against infused factor VIII (FVIII) has a detrimental impact on health and quality of life of patients with hemophilia A. Several observational studies and a recently published randomized trial indicate that the inhibitor risk in previously untreated patients (PUPs) is higher following the use of recombinant FVIII (rFVIII) products compared with plasma-derived FVIII concentrates. There is currently a great interest towards newer rFVIII products that adopt various technological solutions to reduce the inhibitor risk.

Areas covered: This review describes the efficacy and safety of simoctocog alfa (Nuwiq), a human cell-line derived rFVIII developed for the prevention and treatment of bleeding in hemophilia A patients. Particular relevance will be given to the safety aspects of this product, with special emphasis on the rate of inhibitor development, presenting the results of the phase II and III clinical trials on previously treated patients (PTPs) and the interim data from the phase III trial on PUPs.

Expert opinion: The final results from PTP studies and the preliminary data from the PUP study document the high efficacy and safety profile of this rFVIII product, which has the potential to reduce the inhibitor risk in PUPs with severe hemophilia A.