Reactive oxygen species-responsive clicked assembly of gold nanoparticles to enhance photothermal therapy

Abstract

To enhance the efficacy of photothermal therapy (PTT) at tumor sites, we designed a reactive oxygen species (ROS)-responsive gold nanoparticle (AuNP)-based nanosystem in which azide-decorated AuNPs (N₃@AuNPs) and diselenide-coated alkyne-decorated AuNPs (Se/Ak@AuNPs) were separately prepared for selective clicking into nanoclusters when exposed to ROS. Se/Ak@AuNPs were dual-functionalized with alkyne moieties and diselenide linkers embedded in a long chain of polyethylene glycol (PEG) to enable the alkyne moieties of Se/Ak@AuNPs to be inaccessible to the azide moieties of N₃@AuNPs owing to steric hindrance. At tumor sites where the ROS level is elevated due to the increased metabolic activity, cellular receptor signaling, mitochondrial dysfunction, and oncogene activity, the diselenide linkers were cleaved, leading to the liberation of the long PEG chains tethered to AuNPs, and the alkyne moieties could be recognized by the surrounding azide moieties to generate a click reaction. The clicked AuNPs formed clustered nanoparticles with increased size. Upon 808 nm laser irradiation, these large clusters of AuNPs significantly enhanced the photothermal conversion efficiency compared with that of isolated AuNPs. In vitro studies revealed that the AuNP clusters exhibited a noticeably higher apoptosis rate than AuNPs. Therefore, ROS-responsive clicked AuNP clusters can be a potential tool for PTT enhancement in cancer treatment.