Abstract
Neurodegenerative diseases such as Huntington's Disease (HD) have a significant impact on healthcare accessibility and costs. A fatal genetic condition, characterized by the progressive loss of striatal neurons, HD is hindered by the lack of endogenous repair in the adult brain. Recent efforts toward protecting neural circuits through neurotrophic support using brain-derived neurotrophic factor (BDNF) have been suboptimal due to the protein's short half-life and limited diffusion. Addressing this, adeno-associated viral vectors (AAV) can be employed as a delivery tool to spatially transduce cells, enabling the localised production of BDNF with consequential neuron protection and/or plasticity, yet present their own constraints. To overcome these known challenges of AAV gene delivery, an injectable, physiologically stable hydrogel-mimic of the brain's extracellular matrix was fabricated to encapsulate the AAVs. This smart system both shielded and constrained the AAV; optimising transfection and therefore elevated and sustained BDNF presentation at the target site. Here, we achieved high neuroprotection using AAVDJ-BDNF delivered through a hydrogel formed via self-assembling peptide nanoscaffolds. These findings support the notion that the spatiotemporal release of BDNF to striatal neurons, facilitated by engineered biomaterial delivery systems, demonstrates tremendous promise by enhancing the efficacy of gene therapy targeted at slowing neurodegenerative disease progression.