医用99Mo工业化生产技术研发

Current Developments in the Industry Production Process of 99Mo for Medical Use

  • 摘要: 全球研究堆老化导致工业化生产99Mo的靶辐照能力严重不足,以及核不扩散条约限制高浓铀的民用,迫使探索99Mo新的生产工艺技术,并将现有的高浓铀靶向低浓铀靶转换,在新技术探索和靶转换的过程中,造成全球医用99Mo供应短缺。美国、加拿大、欧洲等正在探索医用99Mo商业化稳定供应的新工艺技术,如加速器粒子束、次临界装置、小堆、熔盐堆和溶液堆等辐照靶件,采用新材料和新工艺制备靶件,超临界、离子液体、新型色谱柱等应用于99Mo的制备。低浓铀靶生产逐渐代替高浓铀靶,光核反应工艺已经成熟,低功率研究堆、次临界装置和粒子束等工艺可以解决部分本地放射性药物和核医学的需求,而加速器生产工艺研究活跃,是未来医用99Mo生产的发展方向。

     

    Abstract: The aging of global research reactors has led to a serious shortage of target irradiation capacity for industrial production of 99Mo, as well as restrictions on the civilian use of high enriched uranium under the Nuclear Non Proliferation Treaty. This has forced the exploration of new production processes for 99Mo and the conversion of existing high enriched uranium targets to low enriched uranium targets. In the process of exploring new technologies and target conversion, it has caused a global shortage of medical 99Mo supply, endangering people’s health.The United States, Canada, and Europe are intensifying their exploration of new process technologies for the commercialization and stable supply of medical 99Mo, such as exploring irradiation targets with as accelerator particle beams, subcritical devices, small reactors, molten salt stacks, and solution stacks, using new materials and processes to prepare targets, and applying supercritical, ionic liquids, and new chromatographic columns to the preparation of 99Mo. The production of low enriched uranium targets is gradually replacing high enriched uranium targets. The photonuclear reaction process has matured, and processes such as low-power research reactors, subcritical devices, and particle beams can meet the needs of some local radioactive drugs and nuclear medicine. The active research on accelerator production technology is the development direction of future medical 99Mo production.

     

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