Flexible Double Bonds-Enhanced Photodynamic Therapy toward Antibacterial Resistance.

The relationship between the molecular structure and types of reactive oxygen species (ROS) generated from photosensitizers (PSs) must be understood for advancing photodynamic therapy (PDT). In this study, we synthesized , , and consisting of C-C, C═C, and C≡C bond linkers, respectively, between electron donor and acceptor moieties. Unlike and , containing a flexible C═C bond linker can absorb energy under white light irradiation, which enhances the swing of connected acceptor groups and leads to the formation of a noncoplanar structure. ROS generation experiments and density functional theory (DFT) calculations demonstrated that the formed noncoplanar structure of can narrow the energy gap between the singlet and triplet states (Δ), which facilitated intersystem crossing, thereby enhancing ROS production, and shifted the generation mechanism from Type II to Type I. , , and antibacterial fibers were synthesized using the wet spinning method. Our developed fibers exhibited long-term, good antibacterial properties in both in vitro ( and ) and in vivo (infected mice) wound dressing experiments, showcasing potential as sustainable and biosafe wound dressings to accelerate healing. We herein highlight the (1) guidance for the design strategy of PS and (2) the innovative fibers for medical applications.