体内
抗体调理
化学
体内分布
生物化学
糖基化
糖脂
体外
补体系统
脂质体
聚糖
生物物理学
免疫系统
去唾液酸糖蛋白受体
细胞生物学
血液蛋白质类
离体
鞘糖脂
细胞
磷酰胆碱
溶血
血红蛋白
外体
配体(生物化学)
肽
作者
Yingjie Yu,Xuehan Li,Yu Gao,Shijia Tao,Li X,Lemei Zhao,Wenshuai Han,Hao Fan,Ying Qiu,M Wang,Luying Zhou,Xiaoyan Fang,Wenhua Yang,Haiyang Zhang,Volker Mailänder,Daniel Crespy,Katharina Landfester,Shuai Jiang,Xiangzhao Mao
标识
DOI:10.1002/anie.202520837
摘要
Mimicking cell membrane glycocalyx, saccharide modification of nanoparticles offers a potent means to regulate their in vivo fate. Here, we investigate how glycosylation (i.e., glucose, galactose, fructose, mannose, and N-acetylglucosamine) regulates liposomal nanoparticle interactions with plasma proteins and immune cells, which further determine their biodistribution and therapeutic efficacy. While fructose conferred the greatest enhancement in tumor cell uptake in vitro, N-acetylglucosamine-modified nanoparticles achieved the highest tumor accumulation and markedly attenuated systemic clearance in vivo, highlighting a pronounced disparity between in vitro and in vivo performance. The compromised in vivo efficacy of glycosylated nanoparticles was linked to significant clearance in blood, liver, and spleen, primarily mediated by blood monocytes, hepatic stellate cells, and splenic macrophages. Proteomics revealed that adsorption of immunoglobulin G (IgG) and complement C3 facilitates in vivo clearance of nanoparticles. Moreover, IgG deposition further promotes subsequent C3 binding. Notably, N-acetylglucosamine markedly mitigates IgG and C3 adsorption, leading to prolonged circulation and enhanced tumor accumulation and inhibition. Benefiting from glycosylation-regulated protein corona, doxorubicin-loaded N-acetylglucosamine-modified liposomal nanoparticles achieved superior antitumor efficacy compared with other glycosylated formulations. This study establishes a clear correlation between glycosyl ligand identity, protein corona composition, and in vivo performance, providing fundamental insights for rational design and clinical translation of glycosylated nanomedicines.
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