How Has Molecular Biology Enhanced Our Undertaking of axSpA and Its Management.
Mauro FaticaArianna D'AntonioLucia NovelliPaola TriggianesePaola ConigliaroElisabetta GrecoAlberto BergaminiCarlo PerriconeMaria Sole ChimentiPublished in: Current rheumatology reports (2022)
In addition to the contribution of MHC system, findings emerged about the role of non-HLA genes (as ERAP1 and 2, whose inhibition could represent a new therapeutic approach) and of epigenetic mechanisms that regulate the expression of genes involved in SpA pathogenesis. Increasing evidence of bone metabolism abnormalities secondary to the activation of immunological pathways suggests the development of various bone anomalies that are present in axSpA patients. SpA are a group of inflammatory diseases with a multifactorial origin, whose pathogenesis is linked to the genetic predisposition, the action of environmental risk factors, and the activation of immune response. It is now well known how bone metabolism leads to long-term structural damage via increased bone turnover, bone loss and osteoporosis, osteitis, erosions, osteosclerosis, and osteoproliferation. These effects can exist in the same patient over time or even simultaneously. Evidence suggests a cross relationship among innate immunity, autoimmunity, and bone remodeling in SpA, making treatment approach a challenge for rheumatologists. Specifically, treatment targets are consistently increasing as new drugs are upcoming. Both biological and targeted synthetic drugs are promising in terms of their efficacy and safety profile in patients affected by SpA.
Keyphrases
- bone loss
- bone mineral density
- end stage renal disease
- immune response
- postmenopausal women
- chronic kidney disease
- risk factors
- ejection fraction
- soft tissue
- gene expression
- body composition
- oxidative stress
- bone regeneration
- dna methylation
- poor prognosis
- peritoneal dialysis
- risk assessment
- drug delivery
- case report
- toll like receptor
- combination therapy
- celiac disease