Radiosensitization impact assessment of silica-layered iron oxide nanocomposites with various shell thickness.

Abstract

Silica shell is considered to be a promising design that enhances nanocomposite stability, cellular internalization, and consequentially therapeutic impacts by overcoming their aggregation under physiological conditions. This study addressed synthesizing silica-layered iron oxide-based nanoparticles (SCINPs) with different shell thicknesses (1-SCINPs, 2-SCINPs, 3-SCINPs, and 4-SCINPs). Also, the impact of shell thickness on the nanoparticle's cellular internalization and the radio-sensitizing effect of prepared nano-formulations were assessed. The physical properties of the synthesized nanoparticles were examined using transmission electron microscopy (TEM), atomic force microscopy (AFM), dynamic light scattering (DLS), vibrating sample magnetometry (VSM), and X-ray diffraction (XRD). Cytotoxicity assay, oxidative stress parameters, and comet assay were used to investigate the radio-sensitizing effect of various nanoformulations. Results revealed that the mean diameter of prepared oxide-based nanoparticles (INPs) was about 12.63 ± 1.36 nm, and the shell thickness for 1-SCINPs, 2-SCINPs, 3-SCINPs, and 4-SCINPs was 22.58 ± 3.51, 26.13 ± 1.40, 46.95 ± 3.10 and 60.30 ± 4.30 nm, respectively. Interestingly, we found that in cells treated with 40 μg/ml of INPs, their viability decreased to 44.6 %. Meanwhile, the viability was 41.69 % and 39.4 % for cells treated with 1-SCINPs and 2-SCINPs, respectively. This means that a thicker silica shell led to a decreased impact on radiosensitization. This was attributed to the influence of surface properties and size of SCINPs on their cellular uptake and the secondary electrons' entrapment within thicker shells upon radiation exposure. Cell viability test, comet assay and oxidative stress parameters show that 2-SCINPs formulations had the most potent radiosensitizing effect (with the highest dose enhancement factor equal to 2.1) when combined with radio-treatment. The results suggest that optimizing the silica shell thickness is critical for maximizing the therapeutic efficacy of SCINPs, with 2-SCINPs showing the highest radiosensitization effect.