Near-Infrared Chiroptical Activity Titanium Dioxide Supraparticles with Circularly Polarized Light Induced Antibacterial Activity
Rui Gao, Changlong Hao, Liguang Xu, Xinxin Xu, Jing Zhao, Maozhong Sun, Qing Wang, Hua Kuang, Chuanlai Xu
Abstract
Titanium dioxide (TiO 2 ) has attracted significant attention in the fields of antibacterial activity and pollutant degradation due to its well-known photocatalytic properties. However, the application of TiO 2 is significantly limited by its large band gap width, which only allows excitation by ultraviolet light below 400 nm. Here, we propose the use of surface chiral functionalization of TiO 2 to tune its band gap width, thus enabling it to be excited by near-infrared-region light (NIR), resulting in the effective separation of electron–hole pairs. By controlling the solvent polarity and forming numerous weak interactions (such as hydrogen bonding) between chiral ligands and TiO 2, we successfully prepared chiral TiO 2 superparticles (SPs) that exhibited a broad circular dichroism (CD) absorption at 792 nm. Under circularly polarized light (CPL) at 808 nm, the chiral SPs induced the separation of electron–hole pairs in TiO 2, thus generating hydroxyl and singlet oxygen radicals. Antibacterial tests under CPL in NIR showed that the chiral TiO 2 SPs exhibited excellent antibacterial performance, with inhibition rates of 99.4% and 100% against Gram-positive and Gram-negative bacteria, respectively. Recycling–reuse experiments and biocompatibility evaluation of the material demonstrated that the chiral TiO 2 SPs are stable and safe antibacterial materials, thus indicating the potential application of chiral TiO 2 SPs in antibacterial aspects of medical implants.