作者
Yong Huang,Liping Zhong,Xiaotong Li,Pan Wu,Jian He,Chao Tang,Tang Zhi-ping,Jing Su,Zhen‐Bo Feng,Bing Wang,Yun Ma,Hongmei Peng,Zhihao Bai,Yi Zhong,Ying Liang,Wenxi Lu,Ruiyu Luo,Jinghua Li,Haiping Li,Zhiming Deng,Xianli Lan,Ziqun Liu,Kun Zhang,Yongxiang Zhao
摘要
Abstract In this study, it is shown for the first time that a reduced graphene oxide (rGO) carrier has a 20‐fold higher catalysis rate than graphene oxide in Ag + reduction. Based on this, a tumor microenvironment‐enabled in situ silver‐based electrochemical oncolytic bioreactor (SEOB) which switched Ag + prodrugs into in situ therapeutic silver nanoparticles with and above 95% transition rate is constructed to inhibit the growths of various tumors. In this SEOB‐enabled intratumoral nanosynthetic medicine, intratumoral H 2 O 2 and rGO act as the reductant and the catalyst, respectively. Chelation of aptamers to the SEOB‐unlocked prodrugs increases the production of silver nanoparticles in tumor cells, especially in the presence of Vitamin C, which is broken down in tumor cells to supply massive amounts of H 2 O 2 . Consequently, apoptosis and pyroptosis are induced to cooperatively contribute to the considerably‐elevated anti‐tumor effects on subcutaneous HepG2 and A549 tumors and orthotopic implanted HepG2 tumors in livers of nude mice. The specific aptamer targeting and intratumoral silver nanoparticle production guarantee excellent biosafety since it fails to elicit tissue damages in monkeys, which greatly increases the clinical translation potential of the SEOB system.