Adaptive Response: A Scoping Review of Its Implications in Medicine, Space Exploration, and Beyond.

IF 2.4 4区医学 Q3 PHARMACOLOGY & PHARMACY

Dose-Response Pub Date : 2025-07-19 eCollection Date: 2025-07-01 DOI:10.1177/15593258251360051

Abolfazl Kanani, Julianna Krasowska, Krzysztof W Fornalski, Joseph John Bevelacqua, James Welsh, Smj Mortazavi

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引用次数: 0

Abstract

Objectives: Radiation Adaptive Response (AR) is a biological phenomenon in which exposure to low-dose radiation (LDR) enhances an organism's ability to withstand subsequent higher doses. This scoping review explores AR across multiple disciplines, summarizing evidence, identifying research gaps, and evaluating potential applications in cancer therapy, neurodegenerative disease management, space medicine, and pandemic response.

Methods: A comprehensive review of experimental/clinical studies on AR was conducted, focusing on molecular mechanisms, biological implications, biophysical modeling, and translational applications.

Results: In oncology, AR has shown promise in selectively protecting normal tissues during radiotherapy while sensitizing tumor cells, yet its effects remain cell-type dependent. LDR may manage neurodegenerative diseases by modulating oxidative stress and inflammation. In space medicine, AR-based astronaut selection has been proposed as a novel strategy to mitigate radiation risks during long-term space missions, although empirical validation is lacking. LDR therapy for managing COVID-19 pneumonia has been explored, but ethical concerns and long-term safety risks require further investigation.

Conclusion: Despite AR's potential, its clinical and spaceflight implementation requires mechanistic elucidation, standardized protocols, and rigorous studies. The risks of tumorigenesis, individual variability in AR, and potential immunomodulatory effects must be evaluated before widespread application. Moreover, inconsistent AR appearance complicates its study and clinical use.

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适应性反应：对其在医学、太空探索及其他领域的影响的范围审查。

目的：辐射适应性反应（AR）是一种生物现象，其中暴露于低剂量辐射（LDR）增强生物体承受随后更高剂量的能力。本综述探讨了多个学科的增强现实，总结了证据，确定了研究差距，并评估了在癌症治疗、神经退行性疾病管理、空间医学和大流行应对方面的潜在应用。方法：从分子机制、生物学意义、生物物理建模和转化应用等方面对AR的实验/临床研究进行综述。结果：在肿瘤学中，AR在放疗期间选择性地保护正常组织，同时使肿瘤细胞增敏，但其作用仍然依赖于细胞类型。LDR可能通过调节氧化应激和炎症来控制神经退行性疾病。在太空医学领域，尽管缺乏经验验证，但基于ar的宇航员选择已被提出作为减轻长期太空任务期间辐射风险的新策略。已经探索了治疗COVID-19肺炎的LDR疗法，但伦理问题和长期安全风险需要进一步调查。结论：尽管AR具有潜力，但其临床和航天应用需要机制阐明、标准化协议和严格的研究。在广泛应用之前，必须评估肿瘤发生的风险、AR的个体变异性和潜在的免疫调节作用。此外，不一致的AR外观使其研究和临床应用复杂化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Dose-Response PHARMACOLOGY & PHARMACY-RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

CiteScore

4.90

自引率

4.00%

发文量

140

审稿时长

>12 weeks

期刊介绍： Dose-Response is an open access peer-reviewed online journal publishing original findings and commentaries on the occurrence of dose-response relationships across a broad range of disciplines. Particular interest focuses on experimental evidence providing mechanistic understanding of nonlinear dose-response relationships.