An Update on Extemporaneous Preparation of Radiopharmaceuticals Using Freeze-Dried Cold Kits

Abstract:: The field of nuclear medicine is rapidly evolving due to the high demand of radiopharmaceuticals for diagnostic and therapeutic applications. The availability of a vast array of radioisotopes, improvement in radiolabeling strategies, and advancements in detection systems have also contributed to the progress in this field. Radiopharmaceuticals are mainly classified based on their application as diagnostic or therapeutic radiopharmaceuticals. These are available either as ready to use preparations or prepared at hospital radiopharmacy either using automated synthesis modules or by using freeze-dried cold kit formulations. Availability of freeze-dried cold kits for preparation of varied radiopharmaceuticals for targeting various organs and tissues played an essential role in the extensive use of 99mTc radiopharmaceuticals for diagnostic imaging by single-photon emission computed tomography (SPECT) imaging. Cold kits are especially suitable for the preparation of radiopharmaceuticals labeled with isotopes like 177Lu with relatively long half-life or radionuclides produced by radioisotope generators. A simplified procedure for the preparation of positron emission tomography (PET) radiopharmaceuticals is also desired to achieve images with higher resolution and sensitivity offered by PET. Robust kit formulations will simplify the preparation of PET radiopharmaceuticals and will contribute to extensive applications of positron emitters such as 68Ga. Several therapeutic radiopharmaceuticals are also being made using cold kits of the ligands. This review provides an update on diagnostic and therapeutic radiopharmaceuticals prepared using cold kits.

99mTc Labelling Strategies for the Development of Potential Nitroimidazolic Hypoxia Imaging Agents

Technetium-99m has a rich coordination chemistry that offers many possibilities in terms of oxidation states and donor atom sets. Modifications in the structure of the technetium complexes could be very useful for fine tuning the physicochemical and biological properties of potential 99mTc radiopharmaceuticals. However, systematic study of the influence of the labelling strategy on the “in vitro” and “in vivo” behaviour is necessary for a rational design of radiopharmaceuticals. Herein we present a review of the influence of the Tc complexes’ molecular structure on the biodistribution and the interaction with the biological target of potential nitroimidazolic hypoxia imaging radiopharmaceuticals presented in the literature from 2010 to the present. Comparison with the gold standard [18F]Fluoromisonidazole (FMISO) is also presented.

A Picture of Modern Tc-99m Radiopharmaceuticals: Production, Chemistry, and Applications in Molecular Imaging

Even today, techentium-99m represents the radionuclide of choice for diagnostic radio-imaging applications. Its peculiar physical and chemical properties make it particularly suitable for medical imaging. By the use of molecular probes and perfusion radiotracers, it provides rapid and non-invasive evaluation of the function, physiology, and/or pathology of organs. The versatile chemistry of technetium-99m, due to its multi-oxidation states, and, consequently, the ability to produce a variety of complexes with particular desired characteristics, are the major advantages of this medical radionuclide. The advances in technetium coordination chemistry over the last 20 years, in combination with recent advances in detector technologies and reconstruction algorithms, make SPECT’s spatial resolution comparable to that of PET, allowing 99mTc radiopharmaceuticals to have an important role in nuclear medicine and to be particularly suitable for molecular imaging. In this review the most efficient chemical methods, based on the modern concept of the 99mTc-metal fragment approach, applied to the development of technetium-99m radiopharmaceuticals for molecular imaging, are described. A specific paragraph is dedicated to the development of new 99mTc-based radiopharmaceuticals for prostate cancer.

14 MeV Neutrons for 99Mo/99mTc Production: Experiments, Simulations and Perspectives

Background: the gamma-emitting radionuclide Technetium-99m (99mTc) is still the workhorse of Single Photon Emission Computed Tomography (SPECT) as it is used worldwide for the diagnosis of a variety of phatological conditions. 99mTc is obtained from 99Mo/99mTc generators as pertechnetate ion, which is the ubiquitous starting material for the preparation of 99mTc radiopharmaceuticals. 99Mo in such generators is currently produced in nuclear fission reactors as a by-product of 235U fission. Here we investigated an alternative route for the production of 99Mo by irradiating a natural metallic molybdenum powder using a 14-MeV accelerator-driven neutron source. Methods: after irradiation, an efficient isolation and purification of the final 99mTc-pertechnetate was carried out by means of solvent extraction. Monte Carlo simulations allowed reliable predictions of 99Mo production rates for a newly designed 14-MeV neutron source (New Sorgentina Fusion Source). Results: in traceable metrological conditions, a level of radionuclidic purity consistent with accepted pharmaceutical quality standards, was achieved. Conclusions: we showed that this source, featuring a nominal neutron emission rate of about 1015 s−1, may potentially supply an appreciable fraction of the current 99Mo global demand. This study highlights that a robust and viable solution, alternative to nuclear fission reactors, can be accomplished to secure the long-term supply of 99Mo.