Today it is generally accepted that B cells require cognate interactions with CD4 IntroductionThe most serious complication in replacement therapy with FVIII products is the development of neutralizing antibodies against FVIII (FVIII inhibitors), which is observed in approximately 25% to 30% of patients with severe hemophilia A. 1 Although several genetic 2 and nongenetic 3 factors that contribute to the risk for patients to develop these antibodies have been identified, why some patients develop antibodies while others do not remains largely unknown.Today it is generally accepted that B cells require cognate interactions with CD4 ϩ T cells to develop high-affinity antibodies against protein antigens. 4,5 In line with this perception, several lines of evidence have supported the involvement of CD4 ϩ T cells in the generation of antibody responses against FVIII in patients with hemophilia A and in murine hemophilia models. 6,7 CD4 ϩ T cells express T-cell receptors that recognize antigen-derived peptides (CD4 ϩ T-cell epitopes) presented by MHC class II molecules, which are expressed on specialized antigen-presenting cells. 8 Structural features of both the MHC class II molecule and the peptide determine the specificity of CD4 ϩ T cells that can bind to the MHC class II-peptide complex. 8,9 The conditions under which CD4 ϩ T cells interact with this complex determine whether the immune system reacts with nonresponsiveness, is activated to develop specific antibodies, or is tolerized to suppress antibody responses. 9,10 Therefore, it is crucial to understand which FVIII peptides are presented by MHC class II complexes under conditions of FVIII replacement therapy and how CD4 ϩ T cells interact with MHC class II-FVIII peptide complexes expressed by antigenpresenting cells. The available information on FVIII peptides presented in the context of specific human MHC class II molecules is limited. Several studies used peripheral blood cells of patients and healthy controls 11 to identify CD4 ϩ T-cell epitopes in the A2 domain, 12 A3 domain, 13 and C2 domain of FVIII. 14 However, these studies lack information on the specific MHC class II molecules associated with the FVIII peptides identified. Jacquemin et al identified T-cell epitopes of FVIII using CD4 ϩ T-cell clones isolated from a mild hemophilia A patient carrying an Arg2150His mutation in the C1 domain of FVIII. 15 All clones recognized FVIII peptides encompassing residue Arg2150. Peptides were presented by HLA-DRB1*0401/HLA-DRB4*01 or HLA-DRDRB1*1501/ HLA-DRB5*0101. One of the peptides identified was a promiscuous epitope that bound to several different HLA-DR proteins. James et al used MHC class II tetramers to analyze FVIII-specific CD4 ϩ T cells obtained from a mild hemophilia A patient carrying an Ala2201Pro mutation in the C2 domain of FVIII. 16 Responses of CD4 ϩ T cells to sequences containing Ala2201 (wild-type), Pro2201 (hemophilic), and other predicted T-cell epitopes were evaluated and resulted in the identification of an HLA-DRB1*0101 restricted T-ce...
Key Points• Vaccination against influenza, with and without the adjuvant MF59, decreases the risk of inhibitor development in HA mice.• Decreased FVIII immunogenicity may be attributed to antigenic competition via T-cell chemotaxis toward the site of vaccination.Inflammatory signals such as pathogen-and danger-associated molecular patterns have been hypothesized as risk factors for the initiation of the anti-factor VIII (FVIII) immune response seen in 25% to 30% of patients with severe hemophilia A (HA). In these young patients, vaccines may be coincidentally administered in close proximity with initial exposure to FVIII, thereby providing a source of such stimuli. Here, we investigated the effects of 3 vaccines commonly used in pediatric patients on FVIII immunogenicity in a humanized HA murine model with variable tolerance to recombinant human FVIII (rhFVIII). Mice vaccinated intramuscularly against the influenza vaccine prior to multiple infusions of rhFVIII exhibited a decreased incidence of rhFVIII-specific neutralizing and nonneutralizing antibodies. Similar findings were observed with the addition of an adjuvant. Upon exposure to media from influenza-or FVIII-stimulated lymph node or splenic lymphocytes, naïve CD4 1 lymphocytes preferentially migrated toward media from influenzastimulated cells, indicating that antigen competition, by means of lymphocyte recruitment to the immunization site, is a potential mechanism for the observed decrease in FVIII immunogenicity. We also observed no differences in incidence or titer of rhFVIII-specific antibodies and inhibitors in mice exposed to the live-attenuated measles-mumps-rubella vaccine regardless of route of administration. Together, our results suggest that concomitant FVIII exposure and vaccination against influenza does not increase the risk of inhibitor formation and may in fact decrease anti-FVIII immune responses. (Blood. 2016;127(26):3439-3449)
Because of early termination, the EPIC study hypothesis could not be corroborated. Nonetheless, our data analyses indicate that the current definition of an inhibitor only based on plasma inhibitor activity ≥0.6 BU mL(-1) may not always reflect the presence of FVIII-neutralizing antibodies. The findings of this study teach us that low-level inhibitor activity results need in addition a confirmatory test and/or the assessment of the therapeutic response.
: The objective of this study was to assess the cost-effectiveness of pharmacokinetic-driven prophylaxis in severe haemophilia A patients. A microsimulation model was developed to evaluate the cost-effectiveness of pharmacokinetic-driven prophylaxis vs. standard prophylaxis and estimate cost, annual joint bleed rate (AJBR), and incremental cost-effectiveness ratio over a 1-year time horizon for a hypothetical population of 10 000 severe haemophilia A patients. A dose of 30 IU/kg per 48 h was assumed for standard prophylaxis. Pharmacokinetic prophylaxis was individually adjusted to maintain trough levels at least 1 and 5 IU/dl or less. AJBR was estimated on the relationship between factor VIII (FVIII) levels and bleeding rate reported in the literature. Sensitivity analyses were performed to assess the stability of the model and the reliability of results. The FVIII dose was reduced in the 27.8% of patients with a trough level more than 5 IU/dl on standard prophylaxis, with a negligible impact on AJBR (+0.1 bleed/year). The FVIII dose was increased in the 10.6% of patients with trough levels less than 1 IU/dl on standard prophylaxis, with a significant reduction of AJBR (-1.9 bleeds/year). On average, overall, pharmacokinetic-driven prophylaxis was shown to decrease the AJBR from 1.012 to 0.845 with a slight reduction of the infusion dose of 0.36 IU/kg, with total saving of 5 197&OV0556; per patient-year. Pharmacokinetic-driven prophylaxis was preferable (i.e. more effective and less costly) compared with standard prophylaxis, with savings of 31 205&OV0556; per bleed avoided. Pharmacokinetic-driven prophylaxis, accounting for patients' individual pharmacokinetic variability, appears to be a promising strategy to improve outcomes with efficient use of available resources in severe haemophilia A patients.
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