Adaptación del módulo de 18FDG para la preparación de una disolución inyectable de [18F] fluoruro sódico de conformidad con la Farmacopea Americana (USP 32) y Europea (PhEur 6)

Revista Espanola De Medicina Nuclear Pub Date : 2011-11-01 DOI:10.1016/j.remn.2011.02.002

T. Martínez , B. Cordero , S. Medín , A. Sánchez Salmón

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引用次数: 2

Abstract

Objective

To establish an automated procedure for the preparation of sodium fluoride ¹⁸F injection using the resources available in our laboratory for the preparation of ¹⁸FDG and to analyze the repercussion of the conditioning column of the fluoride ion entrapment on the characteristics of the final product.

Material and method

The sequence of an ¹⁸FDG synthesis module prepared so that it traps the fluoride ion from the cyclotron in ion-exchange resin diluted with 0.9% sodium chloride. The final solution was dosified and sterilized in a final vial in an automatized dispensing module. Three different column conditioning protocols within the process were tested. Quality controls were run according to USP 32 and EurPh 6, adding control of ethanol levels of residual solvent and quality controls of the solution at 8 h post-preparation.

Results

Activation of the resin cartridges with ethanol and water was the chosen procedure, with fluoride ion trapping > 95% and pH around 7. Ethanol levels were < 5.000 ppm. Quality controls at 8 h indicated that the solution was in compliance with the USP 32 and EurPh 6 specifications.

Conclusion

This is an easy, low-cost, reliable automated method for sodium fluoride preparation in PET facilities with existing equipment for ¹⁸FDG synthesis and quality control.

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根据美国药典(USP 32)和欧洲药典(PhEur 6)对18FDG模块进行调整，用于制备注射用氟化钠溶液[18F]

目的利用实验室现有的18FDG制备资源，建立氟化钠18F注射液的自动化制备工艺，并分析氟离子包封调节柱对最终产品特性的影响。材料和方法制备了18FDG合成模块的序列，该模块可以在0.9%氯化钠稀释的离子交换树脂中捕获回旋加速器中的氟离子。最终溶液在自动配药模块中的最终小瓶中进行剂量和灭菌。在此过程中测试了三种不同的柱调节方案。按照USP 32和EurPh 6进行质量控制，添加乙醇残留量控制和制备后8 h溶液质量控制。结果树脂筒采用乙醇和水活化，氟离子捕获;95% pH值在7左右乙醇浓度为<5.000 ppm。8小时的质量控制表明该溶液符合USP 32和EurPh 6规范。结论利用现有的18FDG合成及质量控制设备，在PET设施中制备氟化钠是一种简便、低成本、可靠的自动化方法。

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

Revista Espanola De Medicina Nuclear 医学-核医学

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