Recent advances in self-assembling redox nanoparticles as a radiation protective agent

IF 0.7 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY AIMS Molecular Science Pub Date : 2023-01-01 DOI:10.3934/molsci.2023005
Chitho P. Feliciano, S. Cammas-Marion, Y. Nagasaki
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Abstract

The search for potent radiation-protective drugs for clinical use continues. Studies have, so far, focused on targeting the neutralization of radiation-generated reactive oxygen species (ROS) to protect the cells against the deleterious effects of exposure to ionizing radiation. However, the development of efficacious radioprotective drugs, which are mostly low molecular weight (LMW) compounds, is mainly limited due to their inherent toxicity and rapid excretion from the body. Thus, researchers reformulated these LMW compounds into nano-based formulations. This review discusses recent advances in the use of self-assembling redox nanoparticles as a new group of radioprotective agents. The copolymer micelle (herein referred to as redox nanoparticles; RNP) contains an active part, amino-TEMPO, that effectively scavenges radiation-induced ROS in the body, as demonstrated in vivo. With the use of nanoparticle-based technologies, optimized formulations of these LMW ROS-neutralizers lead to the significant reduction of its toxicity, high bioavailability and longer blood circulation, which consequently resulted in its notable enhanced efficacy (for example, increased survival rate, reduced radiation-induced syndromes and organ damage) against the damaging effects of ionizing radiation. Consistent with the available data on the use of RNP and other nano-based radioprotective agents, it can be concluded that the inherent ROS-targeting activity of a drug intended for radiation protection is as vital as its bioavailability in the specific tissues and organs, where the short-lived ROS are produced during radiation exposure. In this review article, we summarized the current status of the development of radioprotective agents, including our self-assembling radioprotective agents.
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自组装氧化还原纳米粒子作为辐射防护剂的研究进展
为临床使用寻找强效防辐射药物的工作仍在继续。到目前为止,研究主要集中在针对辐射产生的活性氧(ROS)的中和,以保护细胞免受电离辐射的有害影响。然而,有效的辐射防护药物的开发主要受到其固有毒性和体内快速排泄的限制,这些药物大多是低分子量(LMW)化合物。因此,研究人员将这些LMW化合物重新配制成纳米基配方。本文综述了自组装氧化还原纳米粒子作为一种新型辐射防护剂的研究进展。所述共聚物胶束(本文称为氧化还原纳米粒子;RNP含有一种活性成分,氨基- tempo,可有效清除体内辐射诱导的ROS。通过使用纳米颗粒技术,这些LMW ros中和剂的优化配方显著降低了其毒性,提高了生物利用度,延长了血液循环,从而显著增强了其对电离辐射的破坏性影响的疗效(例如,提高了存活率,减少了辐射引起的综合征和器官损伤)。与使用RNP和其他纳米基辐射防护剂的现有数据一致,可以得出结论,用于辐射防护的药物固有的ROS靶向活性与其在特定组织和器官中的生物利用度一样重要,在这些组织和器官中,辐射暴露期间会产生短暂的ROS。本文综述了辐射防护剂的发展现状,包括自组装辐射防护剂的研究进展。
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来源期刊
AIMS Molecular Science
AIMS Molecular Science BIOCHEMISTRY & MOLECULAR BIOLOGY-
自引率
0.00%
发文量
4
审稿时长
5 weeks
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