Neoadjuvant therapy with denosumab in a giant cell tumour. A case report

Introduction: Giant cell tumour (GCT) is a benign but locally aggressive primary osteolytic bone tumour, prone to local recurrence after surgery. Denosumab is a human antibody against RANKL, an over-expressed ligand present on normal multinucleated cells, responsible for bone destruction in GCT. We report the case of a patient with an advanced GCT of the distal radius. The lesion was treated with adjuvant denosumab , followed by curettage. Clinical case: A 28 years old patient presented with a classical honeycomb osteolytic lesion in the left distal radius. Core-needle biopsy confirmed the diagnosis of GCT. Due to the proximity to the radio-carpal joint and advanced scalloping of the metaphyseal cortical bone, joint-salvage surgery was not possible. We initiated a neo-adjuvant treatment with denosumab (XGEVA), 120mg/ week for 1 month, followed by monthly injections for 6 months. During this time, a substantial bone recorticalization, without progression of the size of the tumour was noted. No local or systemic side effects were observed. We performed intra-lesional (curettage) excision and bone grafting after 6 months. Histological analysis revealed islets (10%) of viable tumour cells within fibrous tissue. Post-op evolution was eventless. Discussion: While surgery remains the treatment of choice for GCT, joint-salvage may not always be possible in case of extensive epiphyseal involvement. The presence of osteoclast-like giant cells seems to make those lesions prone to the specific anti-RANKL treatment with denosumab. Denosumab appears to slow down tumour growth and promote recorticalization of eroded bone. It might allow less aggressive surgery in selected cases.

Mutations in the heat-shock protein A9 (HSPA9) gene cause the EVEN-PLUS syndrome of congenital malformations and skeletal dysplasia.

We and others have reported mutations in LONP1, a gene coding for a mitochondrial chaperone and protease, as the cause of the human CODAS (cerebral, ocular, dental, auricular and skeletal) syndrome (MIM 600373). Here, we delineate a similar but distinct condition that shares the epiphyseal, vertebral and ocular changes of CODAS but also included severe microtia, nasal hypoplasia, and other malformations, and for which we propose the name of EVEN-PLUS syndrome for epiphyseal, vertebral, ear, nose, plus associated findings. In three individuals from two families, no mutation in LONP1 was found; instead, we found biallelic mutations in HSPA9, the gene that codes for mHSP70/mortalin, another highly conserved mitochondrial chaperone protein essential in mitochondrial protein import, folding, and degradation. The functional relationship between LONP1 and HSPA9 in mitochondrial protein chaperoning and the overlapping phenotypes of CODAS and EVEN-PLUS delineate a family of "mitochondrial chaperonopathies" and point to an unexplored role of mitochondrial chaperones in human embryonic morphogenesis.

NBAS mutations cause a multisystem disorder involving bone, connective tissue, liver, immune system, and retina.

We report two unrelated patients with a multisystem disease involving liver, eye, immune system, connective tissue, and bone, caused by biallelic mutations in the neuroblastoma amplified sequence (NBAS) gene. Both presented as infants with recurrent episodes triggered by fever with vomiting, dehydration, and elevated transaminases. They had frequent infections, hypogammaglobulinemia, reduced natural killer cells, and the Pelger-Huët anomaly of their granulocytes. Their facial features were similar with a pointed chin and proptosis; loose skin and reduced subcutaneous fat gave them a progeroid appearance. Skeletal features included short stature, slender bones, epiphyseal dysplasia with multiple phalangeal pseudo-epiphyses, and small C1-C2 vertebrae causing cervical instability and myelopathy. Retinal dystrophy and optic atrophy were present in one patient. NBAS is a component of the synthaxin-18 complex and is involved in nonsense-mediated mRNA decay control. Putative loss-of-function mutations in NBAS are already known to cause disease in humans. A specific founder mutation has been associated with short stature, optic nerve atrophy and Pelger-Huët anomaly of granulocytes (SOPH) in the Siberian Yakut population. A more recent report associates NBAS mutations with recurrent acute liver failure in infancy in a group of patients of European descent. Our observations indicate that the phenotypic spectrum of NBAS deficiency is wider than previously known and includes skeletal, hepatic, metabolic, and immunologic aspects. Early recognition of the skeletal phenotype is important for preventive management of cervical instability. © 2015 Wiley Periodicals, Inc.