体内
皮下注射
化学
自愈水凝胶
辐照
激光器
药物输送
生物医学工程
医学
内分泌学
生物
光学
物理
生物技术
有机化学
核物理学
作者
Jinsong Shao,Lingzi Feng,Qingyu Zhao,Chao Chen,Jia Li,Qian Ma,Xiaohan Jiang,Ying Sun,Yanguang Yang,Haiying Gu,Yong Hu,Donglin Xia
标识
DOI:10.1016/j.jconrel.2021.11.021
摘要
Abstract Exogenous insulin (INS) is critical for managing diabetes. However, owing to its short in vivo half-life, frequent injection of INS is un-avoidable, which is both painful and inconvenient, compromising the quality of life. Herein, we developed a laser-regulated INS release system (INS-ICG@ER hydrogel) that allowed an on-demand release of INS from the subcutaneous INS reservoir by remote laser control without the frequent injection of insulin. The amino acid hydrogel functions as a hydrogel 3D scaffold material, which offers increased subcutaneous stability of drug loaded erythrocyte. This INS-ICG@ER hydrogel would release INS due to the elevated content of reactive oxygen species (ROS), generated by ICG under laser irritation. Conversely, the ROS would be scavenged without the laser irradiation and stopped the release of INS from INS-ICG@ER hydrogel. Furthermore, the release of INS from INS-ICG@ER hydrogel could be regulated by laser irradiation. The INS-ICG@ER hydrogels could control the hyperglycemia within 2 h in diabetic mice and maintained their normal blood glucose level (BGL) for up to 6 days with laser irradiation 30 min prior to meals avoiding the frequent injection of free INS. This delivery system is an effective method that offers a spatiotemporally controlled release of INS to control the glucose level in vivo.
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