Disulfiram-loaded CuO2 nanocarriers for enhanced synergistic chemodynamic chemotherapy.

Disulfiram (DSF) metabolites exhibit antitumor properties when bound to Cu2+. This combination also promotes the generation of reactive oxygen species (ROS), ultimately leading to tumor cell death. In this study, CuO2 served as a carrier for DSF, forming a dual-drug delivery system with Cu2+ and DSF encapsulated in polydopamine (PDA). In the final delivery system, CuO2 (DSF-CuO2@PDA) was hydrolyzed at the tumor site, releasing both Cu2+ and H2O2. Cu2+ reacts with DSF metabolites to form Bis(diethyldithiocarbamate)-Cu (CuET), which triggers a Fenton-like reaction that generates ROS. Chemotherapy and chemodynamic therapy exhibited significant tumor-suppressive capabilities, with an inhibition rate of 61 %. In addition, the DSF-CuO2@PDA complex demonstrated superlative tumor-targeting ability and biocompatibility.

Dextran-Based Antibacterial Hydrogel Dressings for Accelerating Infected Wound Healing by Reducing Inflammation Levels.

Infected wounds pose challenges such as exudate management, bacterial infections, and persistent inflammation, making them a significant challenge for modern dressings. To address these issues in infected wounds more effectively, aerogel-hydrogel biphase gels based on dextran are developed. The gel introduced in this study exhibits antibacterial and anti-inflammatory properties in the process of wound therapy, contributing to accelerated wound healing. The aerogel phase exhibits exceptional water-absorption capabilities, rapidly soaking up exudate from infected wound, thereby fostering a clean and hygienic wound healing microenvironment. Concurrently, the aerogel phase is enriched with hydrogen sulfide donors. Following water absorption and the formation of the hydrogel phase, it enables the sustained release of hydrogen sulfide around the wound sites. The experiments confirm that hydrogen sulfide, by promoting M2 macrophage differentiation and reducing the levels of inflammatory factors, effectively diminishes local inflammation levels at the wound site. Furthermore, the sodium copper chlorophyllin component within the hydrogel phase demonstrates effective antibacterial properties through photodynamic antimicrobial therapy, providing a viable solution to wound infection challenges.