https://www.selleckchem.com/products/dmog.html The ANMg5V Silk showed the highest polarization resistance (46.12 kΩ·cm2), protection efficiency (>0.99) and lowest corrosion rate (only 0.017 mm/year) relative to untreated Mg (8.457 mm/year), and anodized Mg (1.039 for anodized at 3 V and 0.986 for anodized at 5 V) surface due to the formation of a pore-free dense biomimetic protective film over Mg surface. The results of the cytotoxicity test confirm that silk-coated samples are significantly less cytotoxic compared to bare and anodized Mg samples. With enhanced corrosion resistance and cytocompatibility, silk-coated Mg could be a potential material for clinical applications.Peripheral nerves injuries (PNIs) still associated with both clinical and social problems. Accordingly, tissue engineers' and surgeons' attentions have been drawn for finding efficient solutions. Herein, scaffolds based on silk fibroin (SF)/raffinose-grafted-GO (S.RafGO) nanocomposite were fabricated. Subsequently, PC12 cells growth in term of number and morphology were investigated on neat SF polymer, SF/GO (S.GO), and S.RafGO scaffolds. Characterization via scanning electron microscopy (SEM) exhibited more fibrous structures with few lamellar nanosheets for S.GO; although, S.RafGO showed extended lamellar with lower fibrous structure. Due to the incorporation of GO and raffinose-GO nanosheets into SF structure, electrical conductivity increased ~30 and 40%, respectively. Water contact angle data revealed that S.RafGO is more wettable than SF and S.GO. Real-time PCR technique detected higher expressions of the β-tubulin, MAP2 genes on S.RafGO scaffolds in comparison with S.GO and the control group. Immunocytochemistry staining studies confirmed the overexpression of neural-specific proteins including nestin, β-tubulin of S.GO, and S.RafGO nanocomposites in comparison with pure SF scaffolds.Applying multifunctional nanocarriers, comprising specifically traceable and tumor targeting moieties, has