AI Article Synopsis
- Titanium dioxide (TiO) nanoparticles, commonly used in sunscreen for UV protection, face challenges due to their high photochemical activity and limited absorption spectrum.
- Researchers have developed a new hybrid nanoparticle, TiO-metal-phenolic network (TiO-MPN NPs), that enhances UV and visible light absorption while reducing harmful reactive oxygen species generated during exposure.
- These TiO-MPN NPs not only improve the sunscreen's effectiveness by increasing protection factors by about four times but also offer an environmentally friendly and biocompatible alternative for sunscreen formulation.
Article Abstract
Titanium dioxide (TiO) nanoparticles are extensively used as a sunscreen filter due to their long-active ultraviolet (UV)-blocking performance. However, their practical use is being challenged by high photochemical activities and limited absorption spectrum. Current solutions include the coating of TiO with synthetic polymers and formulating a sunscreen product with additional organic UV filters. Unfortunately, these approaches are no longer considered effective because of recent environmental and public health issues. Herein, TiO-metal-phenolic network hybrid nanoparticles (TiO-MPN NPs) are developed as the sole active ingredient for sunscreen products through photochemical suppression and absorption spectrum widening. The MPNs are generated by the complexation of tannic acid with multivalent metal ions, forming a robust coating shell. The TiO-MPN hybridization extends the absorption region to the high-energy-visible (HEV) light range via a new ligand-to-metal charge transfer photoexcitation pathway, boosting both the sun protection factor and ultraviolet-A protection factor about 4-fold. The TiO-MPN NPs suppressed the photoinduced reactive oxygen species by 99.9% for 6 h under simulated solar irradiation. Accordingly, they substantially alleviated UV- and HEV-induced cytotoxicity of fibroblasts. This work outlines a new tactic for the eco-friendly and biocompatible design of sunscreen agents by selectively inhibiting the photocatalytic activities of semiconductor nanoparticles while broadening their optical spectrum.
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| http://dx.doi.org/10.1021/acsami.4c00174 | DOI Listing |
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