Bioinspired Jellyfish-like Carbon/Manganese nanomotors with H2O2 and NIR light Dual-propulsion for enhanced tumor penetration and chemodynamic therapy

Chemodynamic therapy (CDT), which catalyzes the production of highly toxic reactive oxygen species (ROS), has been widely used in tumor therapy in the past five years. However, most of the current nanomaterials for CDT are difficult to penetrate into the tumor effectively due to the lack of motility, resulting in an unsatisfactory CDT effect. Herein, bioinspired jellyfish-like carbon/manganese nanomotors (JCMNs) are designed to achieve hydrogen peroxide (H2O2) and NIR light dual-propulsion for the enhanced CDT therapy. Based on the jellyfish -like asymmetric structure, the manganese component can catalyze H2O2 to generate chemical concentration gradient, propelling JCMNs to dynamically generate ROS in cells by self-diffusiophoresis. In addition, the carbon component of JCMNs can absorb near-infrared (NIR) light to produce a temperature gradient, driving JCMNs to enhance tumor penetration by self-thermophoresis. The combination of chemical and NIR light propulsions significantly improves the efficiency of tumor CDT, revealing that it should be a reasonable strategy to promote the development of nanobiomedicine by endowing nanosystems with propulsion capacity.

Automated summary

Chemodynamic therapy (CDT), which catalyzes the production of highly toxic reactive oxygen species (ROS), has been widely used in tumor therapy. However, the effectiveness of CDT is often limited by the poor tumor penetration of current nanomaterials. In this study, bioinspired jellyfish-like carbon/manganese nanomotors (JCMNs) were designed to achieve dual-propulsion for enhanced CDT therapy. The JCMNs utilized hydrogen peroxide (H2O2) and NIR light to propel themselves and improve tumor penetration and ROS generation, leading to improved CDT efficiency.