| Abstract | Lung cancer remains the leading cause of cancer-related mortality worldwide, owing to its aggressive nature, late-stage diagnosis, and resistance to conventional therapies. Gene therapy offers a promising alternative by modulating specific genetic pathways to target cancer cells while sparing healthy ones. This study investigates the potential of chemically functionalized nanoscale graphene oxide (GO) as carriers for delivering therapeutic genes in a 3D tumor microenvironment (TME) model, incorporating lung cancer cells, human lung fibroblasts, and macrophages in a Matrigel-collagen matrix to mimic the structural properties and immune functions. These therapeutic genes, including small interfering RNAs and plasmid DNAs, regulate immune evasion markers (CD47 and CD24) and apoptosis-inducing proteins (ANT1). GO nanocarriers demonstrate preferential uptake in cancer cells, achieving transfection and gene modulation within the TME model. The individual delivery of genes downregulates cancer markers and induces ANT1 expression, resulting in lung cancer cell elimination. Co-delivery of CD47_siRNA and ANT1_pDNA produces synergistic efficacy, enhancing cancer cell elimination. These findings highlight the potential of GO-based gene therapies as a targeted and effective approach for lung cancer treatment, setting the stage for in vivo validation and clinical translation. |
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