Kamendra Kumar, Albert J Fornace, Shubhankar Suman
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引用次数: 0
Abstract
Oxidative stress-mediated biomolecular damage is a characteristic feature of ionizing radiation (IR) injury, leading to genomic instability and chronic health implications. Specifically, a dose- and linear energy transfer (LET)-dependent persistent increase in oxidative DNA damage has been reported in many tissues and biofluids months after IR exposure. Contrary to low-LET photon radiation, high-LET IR exposure is known to cause significantly higher accumulations of DNA damage, even at sublethal doses, compared to low-LET IR. High-LET IR is prevalent in the deep space environment (i.e., beyond Earth's magnetosphere), and its exposure could potentially impair astronauts' health. Therefore, the development of biomarkers to assess and monitor the levels of oxidative DNA damage can aid in the early detection of health risks and would also allow timely intervention. Among the recognized biomarkers of oxidative DNA damage, 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-OxodG) has emerged as a promising candidate, indicative of chronic oxidative stress. It has been reported to exhibit differing levels following equivalent doses of low- and high-LET IR. This review discusses 8-OxodG as a potential biomarker of high-LET radiation-induced chronic stress, with special emphasis on its potential sources, formation, repair mechanisms, and detection methods. Furthermore, this review addresses the pathobiological implications of high-LET IR exposure and its association with 8-OxodG. Understanding the association between high-LET IR exposure-induced chronic oxidative stress, systemic levels of 8-OxodG, and their potential health risks can provide a framework for developing a comprehensive health monitoring biomarker system to safeguard the well-being of astronauts during space missions and optimize long-term health outcomes.
氧化应激介导的生物分子损伤是电离辐射(IR)损伤的一个特征,会导致基因组不稳定和慢性健康影响。具体来说,据报道,在许多组织和生物流体中,红外照射数月后,氧化 DNA 损伤会出现与剂量和线性能量转移(LET)相关的持续性增加。众所周知,与低辐射光子辐射相反,与低辐射红外辐射相比,高辐射红外辐射即使在亚致死剂量下也会导致更高的 DNA 损伤累积。在深空环境(即地球磁层之外)中,高能谱红外辐射非常普遍,暴露在这种辐射下可能会损害宇航员的健康。因此,开发评估和监测 DNA 氧化损伤水平的生物标志物有助于及早发现健康风险,并及时进行干预。在公认的氧化 DNA 损伤生物标志物中,8-氧代-7,8-二氢-2'-脱氧鸟苷(8-OxodG)已成为一种有希望的候选标志物,表明存在慢性氧化应激。据报道,在接受同等剂量的低辐射和高辐射红外照射后,8-OxodG 会表现出不同的水平。本综述讨论了 8-OxodG 作为高强辐射诱导的慢性应激的潜在生物标志物,特别强调了其潜在来源、形成、修复机制和检测方法。此外,这篇综述还探讨了高激光辐射红外照射的病理生物学影响及其与 8-OxodG 的关联。了解高强度线性红外辐射诱导的慢性氧化应激、全身 8-OxodG 水平及其潜在健康风险之间的关联,可为开发全面的健康监测生物标志物系统提供一个框架,以保障宇航员在太空任务期间的健康,并优化长期健康结果。