Engineering 2D Multienzyme-Mimicking Pyroptosis Inducers for Ultrasound-Augmented Catalytic Tumor Nanotherapy.

Overcoming apoptosis resistance is necessary to ensure an effective cancer treatment; however, it is currently very difficult to achieve. A desirable alternative for cancer treatment is the targeted activation of pyroptosis, a unique type of programmed cell death. However, the pyroptosis inducers that are efficient for cancer therapy are limited. This work reports the engineering of 2D NiCoO x nanosheets as inducers of the production of harmful reactive oxygen species (ROS), which promote intense cell pyroptosis, and that can be applied to ultrasound (US)-augmented catalytic tumor nanotherapy. The main therapeutic task is carried out by the 2D NiCoO x nanosheets, which have four multienzyme-mimicking activities: peroxidase- (POD), oxidase- (OXD), glutathione peroxidase- (GPx), and catalase- (CAT) mimicking activities. These activities induce the reversal of the hypoxic microenvironment, endogenous glutathione depletion, and a continuous ROS output. The ROS-induced pyroptosis process is carried out via the ROS-NLRP3-GSDMD pathway, and the exogenous US activation boosts the multienzyme-mimicking activities and favors the incremental ROS generation, thus inducing mitochondrial dysfunction. The anti-cancer experimental results support the dominance of NiCoO x nanosheet-induced pyroptosis. This work expands on the biomedical applications of engineering 2D materials for US-augmented catalytic breast cancer nanotherapy and deepens the understanding of the multienzyme activities of nanomaterials.