Abstract
Neurological disorders present a formidable challenge in modern medicine due to the
intricate obstacles set for the brain and the multipart nature of genetic interventions. This review
article delves into the promising realm of nanoparticle-based gene therapy as an innovative approach
to addressing the intricacies of neurological disorders. Nanoparticles (NPs) provide a multipurpose
podium for the conveyance of therapeutic genes, offering unique properties such as precise
targeting, enhanced stability, and the potential to bypass blood-brain barrier (BBB) restrictions. This
comprehensive exploration reviews the current state of nanoparticle-mediated gene therapy in neurological
disorders, highlighting recent advancements and breakthroughs. The discussion encompasses
the synthesis of nanoparticles from various materials and their conjugation to therapeutic
genes, emphasizing the flexibility in design that contributes to specific tissue targeting. The abstract
also addresses the low immunogenicity of these nanoparticles and their stability in circulation, critical
factors for successful gene delivery. While the potential of NP-based gene therapy for neurological
disorders is vast, challenges and gaps in knowledge persist. The lack of extensive clinical trials
leaves questions about safety and potential side effects unanswered. Therefore, this abstract emphasizes
the need for further research to validate the therapeutic applications of NP-mediated gene therapy
and to address nanosafety concerns. In conclusion, nanoparticle-based gene therapy emerges as
a promising avenue in the pursuit of effective treatments for neurological disorders. This abstract
advocates for continued research efforts to bridge existing knowledge gaps, unlocking the full potential
of this innovative approach and paving the way for transformative solutions in the realm of
neurological health.
Graphical Abstract
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