Chromatographic separation of silver-111 from neutron-irradiated palladium target: toward direct labeling of radiotracers

IF 4.4 Q1 CHEMISTRY, INORGANIC & NUCLEAR EJNMMI Radiopharmacy and Chemistry Pub Date : 2023-12-20 DOI:10.1186/s41181-023-00232-0

Marianna Tosato, Andrea Gandini, Steffen Happel, Marine Bas, Antonietta Donzella, Aldo Zenoni, Andrea Salvini, Alberto Andrighetto, Valerio Di Marco, Mattia Asti

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Abstract

Background

Silver-111 is a promising β⁻-emitting radioisotope with ideal characteristics for targeted radionuclide therapy and associated single photon emission tomography imaging. Its decay properties closely resemble the clinically established lutetium-177, making it an attractive candidate for therapeutic applications. In addition, the clinical value of silver-111 is further enhanced by the existence of the positron-emitting counterpart silver-103, thus imparting a truly theranostic potential to this element. A so-fitting matching pair could potentially overcome the current limitations associated with the forced use of chemically different isotopes as imaging surrogates of lutetium-177, leading to more accurate and efficient diagnosis and treatment. However, the use of silver-111-based radiopharmaceuticals in vivo has faced obstacles due to the challenges related to its production and radiochemical separation from the target material. To address these issues, this study aims to implement a chromatographic separation methodology for the purification of reactor-produced silver-111. The ultimate goal is to achieve a ready-to-use formulation for the direct radiolabeling of tumour-seeking biomolecules.

Results

A two-step sequence chromatographic process was validated for cold Ag-Pd separation and then translated to the radioactive counterpart. Silver-111 was produced via the ¹¹⁰Pd(n,γ)¹¹¹Pd nuclear reaction on a natural palladium target and the subsequent β⁻-decay of palladium-111. Silver-111 was chemically separated from the metallic target via the implemented chromatographic process by using commercially available LN and TK200 resins. The effectiveness of the separations was assessed by inductively coupled plasma optical emission spectroscopy and γ-spectrometry, respectively, and the Ag⁺ retrieval was afforded in pure water. Recovery of silver-111 was > 90% with a radionuclidic purity > 99% and a separation factor of around 4.21·10⁻⁴.

Conclusions

The developed separation method was suitable to obtain silver-111 with high molar activity in a ready-to-use water-based formulation that can be directly employed for the labeling of radiotracers. By successfully establishing a robust and efficient production and purification method for silver-111, this research paves the way for its wider application in targeted radionuclide therapy and precision imaging.

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从中子辐照钯靶中色谱分离银-111：实现放射性同位素的直接标记

背景银-111是一种很有前途的β发射放射性同位素，具有放射性核素靶向治疗和相关单光子发射断层成像的理想特性。它的衰变特性与已在临床上得到证实的镥-177 非常相似，因此在治疗应用方面具有很强的吸引力。此外，银-111 的临床价值因其正电子发射对应物银-103 的存在而得到进一步提升，从而赋予了这种元素真正的治疗潜力。银-111 与镥-177 的化学性质不同，因此有可能克服目前被迫使用不同同位素作为镥-177 成像替代物的局限性，从而提高诊断和治疗的准确性和效率。然而，由于银-111 的生产和从靶材料中进行放射化学分离所面临的挑战，银-111 放射药物在体内的使用一直面临障碍。为了解决这些问题，本研究旨在采用一种色谱分离方法来纯化反应器生产的银-111。最终目标是获得一种即用型配方，用于直接对肿瘤寻找的生物大分子进行放射性标记。结果对冷银钯分离的两步顺序色谱过程进行了验证，然后将其转化为放射性对应物。银-111是通过天然钯靶上的110Pd(n,γ)111Pd核反应以及随后钯-111的β-衰变产生的。使用市售的 LN 和 TK200 树脂，通过色谱法从金属靶上化学分离出银-111。分离效果分别通过电感耦合等离子体光发射光谱法和γ光谱法进行了评估，并在纯水中回收了Ag+。结论所开发的分离方法适用于获得高摩尔活性的银-111，其水基制剂可直接用于放射性核素的标记。通过成功建立一种稳健高效的银-111 生产和纯化方法，这项研究为银-111 在放射性核素靶向治疗和精准成像领域的广泛应用铺平了道路。

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