Exploiting the unique interaction characteristics of fast neutrons for improved cancer therapy: A radiobiological perspective

Q1 Health Professions
Festo Kiragga, Konstantin Brazovskiy
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引用次数: 0

Abstract

Fast neutrons have sufficient energy to liberate recoil protons, alpha particles, and other products when they interact with the nuclei of the target material through scattering and absorption processes. Physical interactions with biological tissues occur mainly with hydrogen nuclei and as the protons interact with the hydrogen in tissues, they create dense ionization chains along their tracks thus depositing energy. Fast neutron therapy was pioneered by Robert Stone in 1938 a few years after the discovery of the neutron. Its main advantage is the limited sensitivity to hypoxia and treatment of slow-growing tumors hence better local control. This is where photon therapy has yet to have much success. Energy deposition by fast neutrons in living tissues is higher than in conventional radiotherapy using mega voltage (MV) photon beams. This higher energy deposition gives fast neutrons a higher relative biological effectiveness (RBE) in dealing with certain tumors. Fast neutrons also have a higher linear energy transfer (LET) and can reach deep-sited tumors better than photon therapy. The main challenge with Fast neutron therapy has been extreme toxicity in late-reacting tissues. Overall, fast neutron therapy holds potential for the treatment of certain tumors by leveraging the unique interaction characteristics of fast neutrons with biological tissues. This review therefore intends to bring this uniqueness to light to enhance the understanding of the radiobiological properties of fast neutrons and the advantages associated with its therapy.

利用快中子独特的相互作用特性改进癌症治疗。放射生物学视角
快中子具有足够的能量,当它们通过散射和吸收过程与目标材料的原子核相互作用时,会释放出反冲质子、α粒子和其他产物。与生物组织的物理相互作用主要发生在氢核上,当质子与组织中的氢相互作用时,它们会沿着轨道产生密集的电离链,从而沉积能量。快中子疗法是罗伯特-斯通在发现中子几年后的 1938 年首创的。它的主要优点是对缺氧的敏感性有限,可治疗生长缓慢的肿瘤,因此局部控制效果更好。这正是光子疗法尚未取得巨大成功的地方。与使用兆伏特(MV)光子束的传统放疗相比,快中子在活体组织中的能量沉积更高。更高的能量沉积使快中子在治疗某些肿瘤时具有更高的相对生物有效性(RBE)。快中子还具有更高的线性能量传递(LET),与光子疗法相比,能更好地到达深部肿瘤。快中子疗法面临的主要挑战是对晚期反应组织的剧毒。总体而言,快中子疗法利用快中子与生物组织的独特相互作用特性,在治疗某些肿瘤方面具有潜力。因此,本综述旨在揭示这种独特性,以加深对快中子放射生物学特性及其治疗优势的了解。
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
Radiation Medicine and Protection
Radiation Medicine and Protection Health Professions-Emergency Medical Services
CiteScore
2.10
自引率
0.00%
发文量
0
审稿时长
103 days
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