Ag/AgO with NIR-Triggered Antibacterial Activities: Photocatalytic Sterilization Enhanced by Low-Temperature Photothermal Effect.

Purpose: A synergistic antibacterial system employing photocatalytic performance and low-temperature photothermal effect (LT-PTT) with the potential for infectious skin wound healing promotion was developed.

Methods: Ag/AgO was synthesized with a two-step method, and its physicochemical properties were characterized. After its photocatalytic performance and photothermal effect were evaluated under 0.

Near-Infrared-Enhanced Dual Enzyme-Mimicking Ag-TiO@Alginate Microspheres with Antibactericidal and Oxygeneration Abilities to Treat Periodontitis.

The effective treatment for periodontitis is to completely and sustainedly eradicate the bacterial pathogens from the complex periodontal pockets. Local sustained-release antibiotics as a complementary treatment after scaling and root planning can sustainedly combat bacterial pathogens in the periodontal pockets to help treat the disease, but the increasing concern of bacterial resistance limits its future use. Here, we reported a local antibacterial system based on microsized multifunctional Ag-TiO encapsulated in alginate (ATA) microspheres.

Photothermal-Enhanced Fenton-like Catalytic Activity of Oxygen-Deficient Nanotitania for Efficient and Safe Tooth Whitening.

The growing demand for charming smiles has led to the popularization of tooth bleaching procedures. Current tooth bleaching products with high-concentration hydrogen peroxide (HP, 30-40%) are effective but detrimental due to the increased risk of enamel destruction, tooth sensitivity, and gingival irritation. Herein, we reported a less-destructive and efficient tooth whitening strategy with a low-concentration HP, which was realized by the remarkably enhanced Fenton-like catalytic activity of oxygen-deficient TiO (TiO).

hDPSC-laden GelMA microspheres fabricated using electrostatic microdroplet method for endodontic regeneration.

The microsphere system has attracted considerable attention as a stem-cell delivery vehicle in regeneration medicine owing to its injectability, fast substance transfer ability, and mimicry of the three-dimensional native environment. However, suitable biomaterials for preparation of microspheres optimal for endodontic regeneration are still being explored. Owing to its excellent bioactivity and biodegradability, gelatin methacryloyl (GelMA) was used to fabricate hydrogel microspheres by the electrostatic microdroplet method, and the potential of GelMA microspheres applied in endodontic regeneration was studied.