Good practices for the automated production of 18F-SiFA radiopharmaceuticals

IF 4.4 Q1 CHEMISTRY, INORGANIC & NUCLEAR EJNMMI Radiopharmacy and Chemistry Pub Date : 2023-10-11 DOI:10.1186/s41181-023-00215-1

Simon Blok, Carmen Wängler, Peter Bartenstein, Klaus Jurkschat, Ralf Schirrmacher, Simon Lindner

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Abstract

Background

The positron emitting isotope fluorine-18 (¹⁸F) possesses almost ideal physicochemical properties for the development of radiotracers for diagnostic molecular imaging employing positron emission tomography (PET). ¹⁸F in its nucleophilic anionic ¹⁸F⁻ form is usually prepared by bombarding an enriched ¹⁸O water target with protons of various energies between 5 and 20 MeV depending on the technical specifications of the cyclotron. Large thick-target yields between 5 and 14 GBq/µA can be obtained, enough to prepare large batches of radiotracers capable to serve a considerable contingent of patients (50 + per clinical batch). The overall yield of the radiotracer however depends on the efficiency of the ¹⁸F labeling chemistry. The Silicon Fluoride Acceptor chemistry (SiFA) has introduced a convenient and highly efficient way to provide clinical peptide-based ¹⁸F-radiotracers in a kit-like procedure matching the convenience of ^99mTc radiopharmaceuticals.

Main body

A radiotracer’s clinical success primarily hinges on whether its synthesis can be automated. Due to its simplicity, the SiFA chemistry, which is based on isotopic exchange (¹⁸F for ¹⁹F), does not only work in a manual setup but has been proven to be automatable, yielding large batches of ¹⁸F-radiotracers of high molar activity (A_m). The production of SiFA radiotracer can be centralized and the radiopharmaceutical be distributed via the “satellite” principle, where one production facility economically serves multiple clinical application sites. Clinically validated tracers such as [¹⁸F]SiTATE and [¹⁸F]Ga-rhPSMA-7/-7.3 have been synthesized in an automated synthesis unit under good manufacturing practice conditions and used in large patient cohorts. Communication of common guidelines and practices is warranted to further the dissemination of SiFA radiopharmaceuticals and to give easy access to this technology.

Conclusion

This current review highlights the most recent achievements in SiFA radiopharmaceutical automation geared towards large batch production for clinical application. Best practice advice and guidance towards a facilitated implementation of the SiFA technology into new and already operating PET tracer production facilities is provided. A brief outlook spotlights the future potential of SiFA radiochemistry within the landscape of non-canonical labeling chemistries.

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18F-SiFA放射性药物自动化生产的良好实践。

背景：正电子发射同位素氟-18（18F）具有几乎理想的物理化学性质，可用于开发正电子发射断层扫描（PET）诊断分子成像的放射性示踪剂。根据回旋加速器的技术规格，其亲核阴离子18F-形式的18F通常通过用5到20MeV之间的各种能量的质子轰击富集的18O水靶来制备。可以获得5至14GBq/µA的大的厚靶产量，足以制备大批量的放射性示踪剂，能够为相当多的患者提供服务（50 + 每个临床批次）。然而，放射性示踪剂的总产量取决于18F标记化学的效率。氟化硅受体化学（SiFA）已经引入了一种方便且高效的方法，以在与99mTc放射性药物的便利性相匹配的试剂盒状程序中提供临床肽基18F放射性示踪剂。主体：放射性示踪剂的临床成功主要取决于其合成是否可以自动化。由于其简单性，基于同位素交换（18F对19F）的SiFA化学不仅在手动设置中工作，而且已被证明是自动化的，产生了大批量的高摩尔活性的18F放射性示踪剂（Am）。SiFA放射性示踪剂的生产可以集中进行，放射性药物可以通过“卫星”原理进行分配，一个生产设施经济地服务于多个临床应用场所。临床验证的示踪剂，如[18F]SiTATE和[18F]Ga-rhPSMA-7/-7.3，已在良好的生产实践条件下在自动化合成装置中合成，并用于大型患者队列。有必要交流共同的指导方针和做法，以进一步传播SiFA放射性药物，并方便使用这项技术。结论：本综述重点介绍了SiFA放射性药物自动化的最新成就，该自动化旨在实现临床应用的大批量生产。提供了最佳实践建议和指导，以促进在新的和已经运行的PET示踪剂生产设施中实施SiFA技术。简要展望了SiFA放射化学在非规范标记化学领域的未来潜力。

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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