充氧
高压氧
医学
化学
重症监护医学
内科学
外科
高压氧
作者
Su‐Mi Choi,Minjeong Kim,Minjun Kim,Su‐Hwan Kim
摘要
, scavenging reactive oxygen species, and modulating the wound microenvironment. Materials such as manganese dioxide, cerium dioxide, platinum nanoparticles, and molybdenum-based quantum dots have demonstrated efficacy in preclinical studies, often exhibiting multiple enzyme-like activities. These nanozymes have shown accelerated wound closure, enhanced angiogenesis, and improved tissue regeneration in animal models. However, challenges remain, including optimizing nanozyme-hydrogel interactions, addressing the potential toxicity of metal-based nanomaterials, and determining optimal oxygen concentrations for various wound conditions. Future research directions include developing biocompatible nanozymes, enhancing delivery systems, and exploring combination therapies. This review underscores the potential of nanozyme-based therapies to revolutionize the treatment of diabetic ulcers and potentially other hypoxia-related conditions.
科研通智能强力驱动
Strongly Powered by AbleSci AI