Enhanced Half-Life Recombinant Factor VIII Concentrates for Hemophilia A: Insights from Pivotal and Extension Studies.

The development of enhanced half-life recombinant factor VIII (EHL-rFVIII) concentrates has improved the management of hemophilia. Furthermore, the chance of maintaining higher trough levels has allowed higher protection from bleeding and, in turn, improved safely performance for certain types of physical activity. The first technology used to improve the pharmacokinetic profile of factor VIII (FVIII) was fusion with the Fc domain of immunoglobulin G. More recently, conjugation to hydrophilic polymers of polyethylene glycol (PEG) has been demonstrated to prolong plasma half-life of FVIII by means of a reduction in clearance of the molecule due to steric hindrance by PEG covering the protein. Here we report results of a systematic review of pivotal studies on EHL-rFVIII concentrates. Significant heterogeneity is observed among different studies on EHL-rFVIII concentrates, and direct comparisons should be avoided. The annualized bleeding rate has ranged between 1.2 and 1.9 in different EHL-rFVIII concentrates, with a progressive further decrease during extension phases of pivotal studies. Zero bleeding was reported by 40 to 45% of patients. Overall, the emerging treatment options seem to be highly effective and safe, associated with a decreased dosing interval to twice weekly or less, which reduces, but does not entirely eliminate, the burden of treatment. Overall, further information is needed from real-life settings to permit differentiation between EHL-FVIII concentrates and for individualizing treatment.

Pathophysiological Role of Synovitis in Hemophilic Arthropathy Development: A Two-Hit Hypothesis.

Despite an increasing access to prophylaxis with clotting factor concentrates, arthropathy still represents the main chronic complication of hemophilia. Whereas previous studies described hemophilic arthropathy (HA) as a degenerative arthropathy, somehow resembling osteoarthritis (OA), most recent evidence suggests that complex inflammatory and immunologic mechanisms are also involved in the pathophysiology of HA. In the present review, we described available data on major mechanisms leading to arthropathic changes in patients with hemophilia, with a specific focus on the role of synovium. The presence of hemosiderin in the joint space induces synovium proliferation, thus leading to formation of several lytic enzymes determining chondrocytes apoptosis and proteoglycans levels reduction. This leads to a direct joint "chemical" damage representing early damages in the pathogenesis of HA (first hit). In parallel, synovial membrane and synovial endothelial cells become a dynamic reservoir of inflammatory cells and mediators, and propagate the inflammatory response (second hit), switching the process from a chemical damage to an inflammatory damage. Overall, consistent data pointed out synovitis as the keystone in HA pathophysiology. This opens novel potential therapeutic targets in this clinical setting.