Biosponge‐Armored Nanodots Restore Redox‐Calcium Homeostasis to Mitigate Reperfusion‐Induced Injury in Ischemic Stroke

材料科学 氧化还原 平衡 纳米点 冲程(发动机) 缺血 生物物理学 纳米技术 内科学 医学 生物 冶金 工程类 机械工程
作者
Xinyue Cao,Ke Shuai,Peng Wang,Jiacheng Xu,Wenqi Pan,Ying Wang,Xiaoyan Li,Weiping Lu,Kai Chen,Yu Chen,Bingcang Huang,Liang Chen
出处
期刊:Advanced Functional Materials [Wiley]
卷期号:35 (50) 被引量:3
标识
DOI:10.1002/adfm.202503183
摘要

Abstract Antioxidant nanomaterials demonstrate significant neuroprotective potential in mitigating reperfusion injury associated with ischemic stroke. However, emerging nanocatalytic strategies targeting oxidative stress suffer from limited therapeutic efficacy owing to their reliance on singular mechanisms of action. In this study, ultrasmall iridium (Ir)‐based catalytic nanodots encapsulated in biopolymers (HIr‐PS) are developed to address ischemic stroke by concurrently normalizing redox and calcium homeostasis. The engineered HIr‐PS is found to possess multiple antioxidant enzyme‐mimetic activities and exhibits superior reactive oxygen species (ROS)‐scavenging efficacy compared to that of bare Ir and IrO 2 nanodots. Surface‐functionalized biopolymers act as sponges to selectively sequester excess intracellular calcium through coordination interactions. This dual function enables HIr‐PS to protect neuronal cells from oxidative stress, restore mitochondrial function, and alleviate endoplasmic reticulum stress. Consequently, HIr‐PS treatment promotes neuronal survival and remodels the pro‐inflammatory microenvironment, as validated in a mouse model of middle cerebral artery occlusion. Mechanistically, these effects are attributed to the abilities of HIr‐PS to penetrate the blood–brain barrier and disrupt the vicious loop of ROS overproduction and calcium overload. This study presents a distinct paradigm for biopolymer‐coated ultrasmall catalytic nanodots as a non‐pharmaceutical neuroprotective strategy for ischemic stroke treatment.
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