内质网
细胞生物学
活性氧
氧化应激
体内
未折叠蛋白反应
炎症
化学
细胞凋亡
发病机制
程序性细胞死亡
体外
信号转导
抗氧化剂
细胞损伤
肠粘膜
医学
细胞
机制(生物学)
癌症研究
生物
药理学
病态的
细胞信号
作者
He‐Ping Zuo,Jia Yang,Wei Zhao,Min Yang
摘要
Sepsis-associated intestinal injury represents a critical pathological event contributing to multiple organ dysfunction, with its pathogenesis closely linked to excessive oxidative stress and hyperactivated endoplasmic reticulum stress. Current clinical interventions lack the capacity for precise modulation of the intestinal microenvironment, while existing nanozyme systems generally face challenges such as low oral delivery efficiency, insufficient stability, and uncertain biosafety. To address these limitations, we developed a novel oral nanozyme delivery system based on 2D V2C MXene. Through surface modification with hydroxyethyl cellulose (HEC), we constructed a V2C@HEC (CV) nanozyme with enhanced physiological stability and intestinal mucoadhesion. In both in vitro and in vivo studies, the CV nanozyme demonstrated significant reactive oxygen species (ROS)-scavenging capacity. Oral administration of CV effectively mitigated intestinal barrier damage and improved survival in a septic mouse model. Mechanistic investigations suggested that the protective effects of CV may be associated with ROS clearance and modulation of endoplasmic reticulum stress, with inhibition of the ATF6/CHOP signaling pathway potentially serving as one underlying mechanism for its cytoprotective function. In summary, this study not only presents a novel nanozyme material with favorable biocompatibility, excellent stability, and a defined antioxidant mechanism, but also provides an innovative materials-based strategy for the treatment of sepsis.
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