Two-dimensional intermetallic PtBi/Pt core/shell nanoplates overcome tumor hypoxia for enhanced cancer therapy
Yongchun Liu, Xinhao Li, Yu Shi, Youjuan Wang, Xiaojing Zhao, Xiangyang Gong, Ren Cai, Guosheng Song, Mei Chen, Xiaobing Zhang
Abstract
The design of multifunctional nanoplatforms is of great importance for improving hypoxia-induced therapeutic outcomes, especially for overcoming radiotherapy (RT) tolerance. Here, two-dimensional intermetallic PtBi/Pt nanoplates (PtBi NPs) were designed as a therapeutic platform to in situ generate oxygen, and thereby overcome tumor hypoxia for boosting photothermal/radiotherapy (PTT/RT). With high X-ray attenuation coefficient, PtBi NPs exhibited outstanding radiotherapy sensitization characteristics. Moreover, the high photothermal effect of PtBi NPs could promote the catalytic activity of PtBi NPs to achieve a synergistic PTT/RT effect. PEGylated PtBi NPs (PtBi-PEG) exhibited excellent biocompatibility, prolonged blood circulation time and enhanced tumor accumulation. Finally, PtBi-PEG showed excellent trimodal contrast enhancement for infrared (IR) imaging, photoacoustic (PA) imaging and X-ray imaging, facilitating imaging-guided cancer therapy. Thus, our work highlights PtBi-PEG as a novel multifunctional theranostic nanoplatform with great potential for future multimodal imaging-guided synergistic cancer therapy.