To develop a novel approach for increasing radiosensitivity in glioblastoma (GBM) by using targeted nanoparticles to deliver siRNA aimed at silencing the EGFR and RELA/P65 genes, which are implicated in radioresistance. We engineered biodegradable, tumor-targeted, self-assembled, and stimuli-responsive peptide nanoparticles for efficient siRNA delivery. We evaluated the nanoparticles' ability to induce gene silencing and enhance DNA damage under radiation in vitro and in vivo. The nanoparticles were designed to exhibit pH-responsive endosomal escape and αvβ3 integrin targeting, allowing for preferential accumulation at tumor sites and traversal of the blood-brain tumor barrier. The application of these nanoparticles resulted in significant gene silencing, increased apoptosis, and decreased cell viability. The treatment impaired DNA repair mechanisms, thereby enhancing radiosensitivity in GBM cells. In a GBM mouse model, the combination of nanoparticle treatment with radiotherapy notably prolonged survival without apparent toxicity. Our findings suggest that nanoparticle-mediated dual gene silencing can effectively overcome GBM radioresistance. This strategy has the potential to improve clinical outcomes in GBM treatment, proposing a promising therapeutic avenue for this challenging malignancy.
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