纳米载体
药物输送
纳米技术
活性氧
计算生物学
药品
靶向给药
生物相容性材料
化学
药物发现
再生医学
药物开发
化学生物学
系统生物学
纳米医学
生物信息学
毒品携带者
临床前研究
转化式学习
翻译科学
生物
表面改性
药理学
细胞生物学
有效载荷(计算)
光动力疗法
氧化还原
仿形(计算机编程)
精密医学
氧化应激
细胞保护
控制释放
计算机科学
作者
Urmila Kafle,Rajan Thapa,Nisha Panth,Newton Suwal,Saroj Bashyal,Rohit Bhatia,Monica Arora,Dinesh Kumar Chellappan,Gaurav Gupta,Monica Gulati,Sachin Kumar Singh,Trudi Collet,Vandana Patravale,Indu Pal Kaur,Kamal Dua,Keshav Raj Paudel
标识
DOI:10.1016/j.colsurfb.2026.115559
摘要
Reactive oxygen species play an integral role in physiological signaling but contribute to pathology when dysregulated. Elevated ROS levels in diseased tissues such as tumors, inflamed sites, and ischemic regions present unique biochemical triggers for targeted drug delivery. Furthermore, strategies utilizing exogenously generated ROS (e.g., via photodynamic action) provide an alternative route for spatiotemporal control. This review summarizes recent advances in ROS-responsive systems, beginning with the chemistry of ROS-cleavable linkers and the design of nanocarrier platforms capable of spatiotemporally controlled release. The integration of these carriers with theranostic functions is highlighted as a strategy to enhance selectivity and reduce systemic toxicity. Applications across oncology, inflammatory disorders, ischemia-reperfusion injury, and regenerative medicine illustrate the breadth of therapeutic potential. Key design considerations including sensitivity thresholds, payload compatibility, and surface functionalization are discussed alongside translational challenges such as stability, reproducibility, and scalability. Emerging opportunities, notably patient-specific redox profiling and biosensor-guided adaptive delivery are identified as promising routes to clinical translation. By bridging redox biology with materials science and nanomedicine, ROS-triggered drug delivery platforms demonstrate the capacity to exploit endogenous oxidative cues for improved therapeutic precision and safety, positioning them as a transformative approach in the development of next-generation controlled release systems.
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