Children’s Hospital of Fudan University, Sydney Children’s Hospital and the University of Sydney have jointly patented new antibody-drug conjugates comprising an antibody targeting GD2 ganglioside covalently linked to cytotoxic drugs potentially useful for the treatment of osteosarcoma.
Understanding epi-transcriptome changes in diffuse midline gliomas H3 K27-altered (DMGs) could provide novel therapeutic options. RNA N6-methyladenosine (m6A) is a key epi-transcriptomic modification regulating RNA processes. A recently published study from the University of Sydney and collaborating institutions aimed to explore the m6A landscape in DMG.
A University of Sydney patent details new cyclic peptides acting as coagulation factor XIa inhibitors reported to be useful for the treatment of thrombosis.
Researchers at the University of Sydney have uncovered a mechanism that may explain why glioblastoma returns after treatment, and the world-first discovery offers new clues for future therapies. Glioblastoma is one of the deadliest brain cancers, accounting for about half of all brain tumors, with a median survival rate of just 15 months. Despite surgery and chemotherapy, more than 1,250 clinical trials over the past 20 years have struggled to improve survival rates.
Glucocorticoid replacement therapy is the current standard of care for congenital adrenal hyperplasia (CAH). However, new therapeutic strategies that can better recapitulate physiological requirements and reduce morbidity and mortality among CAH patients are urgently needed. Despite the promise of gene therapy for correcting monogenic disorders, the strategies investigated to date have not yielded satisfactory results.
University of Sydney has synthesized translocator protein (TSPO; PBR) (A147T mutant) ligands reported to be useful for the diagnosis and treatment of neurological disorders.
New single-step genome editing techniques that enable the insertion, inversion or deletion of long DNA sequences at specified genome positions have been demonstrated in bacteria.
New single-step genome editing techniques that enable the insertion, inversion or deletion of long DNA sequences at specified genome positions have been demonstrated in bacteria.
New single-step genome editing techniques that enable the insertion, inversion or deletion of long DNA sequences at specified genome positions have been demonstrated in bacteria. The advance opens the door to the development of programmable methods for rearranging DNA, using recombinase enzymes guided by RNA. The two different approaches to using insertion sequences (IS) – some of the simplest and most compact mobile genetic elements – are described in two papers published in Nature and Nature Communications.
CTNNB1 syndrome is a rare neurodevelopmental disorder that is caused by mutations in the gene encoding β-catenin, CTNNB1, which plays a critical role in neuronal development, synapse formation and brain maturation.