开发基于钛合金的个性化近距离放射治疗辐射源的经验

Q4 Medicine
D. Chuvilin, I. I. Skobelin, A. V. Kurochkin, K. A. Makoveeva, A.N. Strepetov, P. A. Karalkin, M.A. Karalkina, I.V. Reshetov
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引用次数: 0

摘要

目的:本研究通过测量施用器植入物的辐射成分及其剂量特性,探讨利用在中子通量反应堆中活化的钛合金制造个性化近距离治疗辐射源的可能性。材料和方法使用添加剂选择性激光熔化装置用钛合金制作近距离放射源的三维植入物。在 IR-8 反应堆的水平实验通道中对钛三维原型进行了为期三天的辐照。随后,使用光谱仪测量了辐照植入物的伽马射线光谱,并使用剂量辐射计测量了三维植入物的剂量特性。结果在我们获得的实验性三维植入体中,放射性核素 47Sc 的放射性活度最高。目前,47Sc 被认为是近距离放射治疗的理想候选材料。作为一种β发射体,它具有诱人的核物理特性,可衰变为 47Ti 的基态(27%)(Eβmax = 600 keV)和 47Ti 的激发态(Eβmax = 439 keV),半衰期为 3.4 天。此外,47Sc 发出的 γ 射线能量为 159 千伏安(68%),适合成像,可用于 SPECT 或平面闪烁成像,并可获得药物在体内的分布情况。在实验植入物中,还检测到了少量的钪放射性核素--46Sc 和 48Sc,它们会发出足够硬的伽马射线,这可能会给患者剂量的确定带来问题。使用富集度超过 95%、经济实惠的钛-47 的优势已经得到证明,它可以产生足够用于治疗的 47Sc 高放射化学产量。结论通过三维打印技术,可以生产出定制的近距离放射治疗器,具有特定的尺寸,并能将任意形状的放射源输送到肿瘤区域,实现肿瘤疾病的个性化治疗。在研究核反应堆的中子通量中激活基于钛合金的放射源时,放射性核素钪-47的活性最高。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Experience in Developing Radiation Sources for Personalized Brachytherapy Based on Titanium Alloys
Purpose: The study explores the possibility of manufacturing radiation sources for personalized brachytherapy using titanium alloys, activated in a neutron flux reactor, by measuring the radiation composition of applicator implants and their dosimetric characteristics. Material and methods: A 3D implant of a brachytherapy source was made from a titanium alloy using an additive selective laser melting setup. The titanium 3D prototype was irradiated for three days in the horizontal experimental channel of the IR-8 reactor. Subsequently, measurements of the gamma-ray spectrum from the irradiated implant were carried out on a spectrometer, and dose characteristics of the 3D implant were measured using a dosimeter-radiometer. Results: In the experimental 3D implant obtained by us, the radionuclide 47Sc exhibits the highest activity. Currently, 47Sc is considered a promising candidate for brachytherapy. It possesses attractive nuclear and physical properties as a β-emitter, decaying into the ground state (27 %) of 47Ti (Eβmax = 600 keV) and the excited state of 47Ti (Eβmax = 439 keV) with a half-life of 3.4 days. Additionally, 47Sc emits γ-radiation at an energy of 159 keV (68 %), which is suitable for imaging, allowing for SPECT or planar scintigraphy and obtaining a picture of the drug’s distribution in the body. In the experimental implant, small amounts of scandium radionuclides – 46Sc and 48Sc, were also detected, emitting sufficiently hard gamma radiation, which can pose a problem for patient dosage determination. The advantages of using titanium-47 with an enrichment of over 95 %, economically available, have been demonstrated, allowing for high radiochemical yields of 47Sc, sufficient for therapy. Conclusion: The 3D printing technology allows the production of a customized applicator for brachytherapy of specific dimensions and the delivery of arbitrarily-shaped sources to the tumor area for personalized therapy of oncological diseases. When implanting sources based on titanium alloys activated in a neutron flux of a research nuclear reactor, the radionuclide scandium-47 exhibits the highest activity.
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来源期刊
Medical Radiology and Radiation Safety
Medical Radiology and Radiation Safety Medicine-Radiology, Nuclear Medicine and Imaging
CiteScore
0.40
自引率
0.00%
发文量
72
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