呼吸医学中的抗氧化策略。

Melpo Christofidou-Solomidou, Vladimir R Muzykantov
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引用次数: 116

摘要

肺氧化应激在急性肺损伤/成人呼吸窘迫综合征(ALI/ARDS)、高氧、缺血再灌注、败血症、辐射损伤、肺移植、COPD和炎症等疾病中起重要的发病作用。活性氧(ROS)由活化的巨噬细胞和白细胞释放或在肺上皮细胞和内皮细胞中形成,损害肺部并启动促炎反应级联,传播肺部和全身应激。包括小有机化合物(如谷胱甘肽、生育酚(维生素E)、类黄酮)在内的多种分子作为天然抗氧化剂,可减少氧化细胞成分、分解活性氧并解毒氧化产物。抗氧化酶可以促进这些抗氧化反应(如使用谷胱甘肽作为还原剂的过氧化物酶)或直接分解ROS(如超氧化物歧化酶[SOD]和过氧化氢酶)。许多抗氧化剂正在被测试用于治疗肺氧化应激。在动物和人体研究中,通过口服、气管内和血管途径给予小剂量抗氧化剂治疗短期和长期氧化应激显示出相当适度的保护作用。目前正在测试气管内和血管内给药抗氧化酶治疗急性氧化应激。例如,气管内给药重组人SOD对暴露于高氧环境的早产儿具有保护作用。然而,动物和人体研究表明,需要更有效地将药物输送到经历氧化应激的细胞中,以提高保护作用。抗氧化剂的多种递送系统,包括脂质体、化学修饰(如掩蔽聚乙二醇[PEG]-基团的附着)和偶联到亲和载体(如抗细胞粘附分子的抗体),目前正在被使用和测试,主要在动物身上,在有限程度上,在人类身上,用于氧化应激的治疗。然而,为了在临床实践中开发和建立有效的肺抗氧化干预措施,还需要进一步的研究。虽然超出了本综述的范围,但抗氧化基因疗法可能最终为亚急性和慢性肺氧化应激的管理提供一种策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Antioxidant strategies in respiratory medicine.

Pulmonary oxidant stress plays an important pathogenetic role in disease conditions including acute lung injury/adult respiratory distress syndrome (ALI/ARDS), hyperoxia, ischemia-reperfusion, sepsis, radiation injury, lung transplantation, COPD, and inflammation. Reactive oxygen species (ROS), released from activated macrophages and leukocytes or formed in the pulmonary epithelial and endothelial cells, damage the lungs and initiate cascades of pro-inflammatory reactions propagating pulmonary and systemic stress. Diverse molecules including small organic compounds (e.g. gluthatione, tocopherol (vitamin E), flavonoids) serve as natural antioxidants that reduce oxidized cellular components, decompose ROS and detoxify toxic oxidation products. Antioxidant enzymes can either facilitate these antioxidant reactions (e.g. peroxidases using glutathione as a reducing agent) or directly decompose ROS (e.g. superoxide dismutases [SOD] and catalase). Many antioxidant agents are being tested for treatment of pulmonary oxidant stress. The administration of small antioxidants via the oral, intratracheal and vascular routes for the treatment of short- and long-term oxidant stress showed rather modest protective effects in animal and human studies. Intratracheal and intravascular administration of antioxidant enzymes are being currently tested for the treatment of acute oxidant stress. For example, intratracheal administration of recombinant human SOD is protective in premature infants exposed to hyperoxia. However, animal and human studies show that more effective delivery of drugs to cells experiencing oxidant stress is needed to improve protection. Diverse delivery systems for antioxidants including liposomes, chemical modifications (e.g. attachment of masking pegylated [PEG]-groups) and coupling to affinity carriers (e.g. antibodies against cellular adhesion molecules) are being employed and currently tested, mostly in animal and, to a limited extent, in humans, for the treatment of oxidant stress. Further studies are needed, however, in order to develop and establish effective applications of pulmonary antioxidant interventions useful in clinical practice. Although beyond the scope of this review, antioxidant gene therapies may eventually provide a strategy for the management of subacute and chronic pulmonary oxidant stress.

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