Fabry disease (FD) is an X-linked lysosomal storage disorder resulting from the deficiency of the hydrolytic enzyme α-galactosidase A (α-Gal A), with consequent accumulation of globotrioasoylceramide in cells and tissues of the body, resulting in a multi-system pathology. Classically affected hemizygous males may display all the characteristic neurological (pain), cutaneous (angiokeratoma), renal (proteinuria, kidney failure), cardiovascular (cardiomyopathy, arrhythmia), and cerebrovascular (transient ischemic attacks, strokes) signs of the disease, while heterozygous females have symptoms ranging from very mild to severe. End-stage renal disease and cardiovascular or cerebrovascular complications limit life-expectancy of untreated patients. Demonstration of α-Gal A deficiency is the definitive method for the diagnosis of hemizygous males, while it's often inconclusive due to random X-chromosomal inactivation so that molecular testing (genotyping) of females is mandatory. The treatment options for FD are enzyme replacement therapy (ERT), and the oral pharmacological chaperone migalastat. Two different products, agalsidase alfa and agalsidase beta, have been commercially available in Europe for 20 years and they are both indicated for long-term ERT. In fact, clinical trials, observational studies and registry data have provided abundant evidence for the safety and efficacy of ERT in improving symptoms and disease progression. Agalsidase alpha and beta are two almost identical recombinant proteins although they are used clinically with a different dosage regimen. In this chapter we aim to clarify the differences between the two ERTs and how these can affect the pharmacokinetic/pharmacodynamic (PK/PD) characteristics and ultimately the risk/benefit profile. The chaperone migalastat, available in Europe since 2016, is the only oral treatment for FD, and acts stabilizing specific mutant forms of α-Gal, defined "amenable" to migalastat. A multitude of therapies are now under investigation in various phases of clinical trials. These include pegylated form of α-Gal (pegunigalsidase alpha), gene therapy (both in-vivo and ex-vivo methods), mRNA therapy (inducing production of α-Gal) and substrate reduction therapy (inhibitors of glucosylceramide synthase leading to reduction of Gb-3).
Read full abstract