Au-Silica nanowire nanohybrid as a hyperthermia agent for photothermal therapy in the near-infrared region.

Nanomaterial-based photothermal therapy has shown great potential for efficient cancer treatment. Here, we report a new hyperthermia agent, Au-silica nanowire nanohybrid (Au-SiNW nanohybrid) with tunable optical properties, for photothermal therapy. The unique feature of the synthetic method is no need of surface modification of SiNWs for the direct deposition of Au seeds, which can avoid complicated synthetic procedures and improve the reproducibility. The Au-SiNW nanohybrid can generate significant amount of heat upon irradiation in the near-infrared (NIR) region for inducing thermal cell death. Moreover, compared to reported hyperthermia nanomaterials, the new nanohybrid requires a much lower laser irradiation density of 0.3 W/cm(2) for destroying cancer cells. A549 lung cancer cells were used for in vitro photothermal study. The nanohybrid showed excellent in vitro biocompatibility by using a 96-nonradioactive-cell proliferation assay. Even at a high concentration of 0.500 mg/mL nanohybrid, over 80% cells were alive. In contrast, almost all the cells were killed when NIR irradiation was applied at a concentration of 0.100 mg/mL nanohybrid. The Au-SiNW nanohybrid may become a promising hyperthermia agent.

Development of gold nanoparticle-enhanced fluorescent nanocomposites.

A gold nanoparticle-enhanced fluorescent nanocomposite was developed. The designed nanocomposite contained a spherical gold nanoparticle core, a thin PVP coating layer, a silica spacer, and a fluorescent dye layer in the silica matrix. The dye molecules were conjugated to a polymer to be effectively doped in the nanocomposites. Different sized gold nanoparticle cores were used while the spacer thickness was varied. The function of the PVP layer in the fabrication of the nanocomposites was discussed. The fluorescence enhancement effects of the metal core size (gold nanoparticles) and the distance between the fluorescent molecules and the metal core were systematically studied. A series of control experiments were conducted to ensure the accuracy of the fluorescence enhancement measurement. The results showed that the developed nanocomposite can effectively enhance the fluorescence signal of the doped dye conjugates. An enhancement factor of 9.2 was obtained when the nanocomposite contained a 13.7 ± 1.3 nm gold nanoparticle core and a 36.6 ± 4.4 nm silica spacer. It is expected that the developed nanocomposite could be an effective model for studying various effects and the mechanism of metal-enhanced fluorescence at the nanoscale.

Shape-tunable hollow silica nanomaterials based on a soft-templating method and their application as a drug carrier.

A one-step soft-templating method for synthesizing shape-tunable hollow silica nanomaterials was developed in a reliable and highly reproducible way. For the first time, both nonspherical and spherical shapes with hollow interiors, including nanowire, nanospheres, and nanotadpole, were successfully obtained by simply changing the solvent. Poly(vinylpyrrolidone) (PVP)-water droplets were used as soft templates for the formation of hollow structures, while three different solvents, including 1-propanol, 1-pentanol, and ethanol, led to the designed shapes. It was found that the solvent, the formation of PVP-water droplets, the amount of ammonia, and the reaction time had great effects on the morphology of synthesized hollow nanomaterials. The effect of various factors on the morphology was systematically studied to propose a growth mechanism. The obtained hollow silica nanomaterials showed excellent reproducibility and great potential for a large-scale synthesis. Finally, the application of the developed hollow silica nanomaterials was demonstrated using the hollow spherical silica nanoparticles. Its drug-carrying ability was studied. The results could be extended for doping various target molecules into the hollow structures for a broad range of applications.