Sulfur Vacancy-Rich Bi<sub><b>2</b></sub>S<sub>3<b>–</b><b><i>x</i></b></sub>–Pt Heterojunction with Multi-enzymatic Activities for Enhanced Sonodynamic Therapy
Wanying Sun, Xiaoxiao Yan, Yingshu Li, Nianqi Meng, Yufeng Feng, Wei Li, Xiaolu Guo, Xing‐Can Shen, Cunji Gao
Abstract
Although bismuth sulfide (Bi 2 S 3 ) possesses a narrow bandgap, advantageous for sonodynamic therapy (SDT), a substantial portion of ultrasound (US)-excited electrons is lost due to rapid electron–hole pair recombination, hindering their surface participation in redox reactions. In this study, a sulfur vacancy engineering strategy was implemented to yield Bi 2 S 3– x with in situ -generated abundant sulfur vacancies, which significantly enhanced electron–hole pair separation for reactive oxygen species (ROS) production under US irradiation. Subsequently, platinum (Pt) nanoparticles were in situ grown on the Bi 2 S 3– x surface, forming a Bi 2 S 3– x –Pt Schottky heterojunction and optimizing catalytic activity. These Pt nanoparticles functioned as electron traps, inducing upward energy band bending and establishing a Schottky barrier, thereby bolstering electron–hole pair separation under US stimulation. Furthermore, the catalase (CAT)- and peroxidase (POD)-like activities of the Pt nanoparticles mitigated tumor hypoxia to augment SDT-induced singlet oxygen generation and triggered oxidative stress, respectively. Sono-excited holes were capable of depleting excessive intratumoral glutathione (GSH) and decomposing hydrogen peroxide into O 2, thus alleviating tumor hypoxia and consequently remodeling the tumor microenvironment. To further enhance tumor targeting and dispersity, Bi 2 S 3–x –Pt was modified with hyaluronic acid (HA), which specifically binds to CD44 receptors overexpressed on tumor cells. Bi 2 S 3–x –Pt@HA, exhibiting these combined functionalities, significantly suppressed tumor proliferation. This study outlines a methodology for enhancing the ROS generation efficiency of inorganic sonosensitizers characterized by narrow bandgaps.