Cyclotron production of 44Sc: From bench to bedside.

Introduction 44 Sc, a PET radionuclide, has promising decay characteristics (T 1/2 = 3.97 h, Eβ + av = 632 keV) for nuclear imaging and is an attractive alternative to the short-lived 68 Ga (T 1/2 = 68 min, Eβ + av = 830 keV). The aim of this study was the optimization of the 44 Sc production process at an accelerator, allowing its use for preclinical and clinical PET imaging. Methods 44 CaCO 3 targets were prepared and irradiated with protons (~ 11 MeV) at a beam current of 50 μA for 90 min. 44 Sc was separated from its target material using DGA extraction resin and concentrated using SCX cation exchange resin. Radiolabeling experiments at activities up to 500 MBq and stability tests were performed with DOTANOC by investigating different scavengers, including gentisic acid. Dynamic PET of an AR42J tumor-bearing mouse was performed after injection of 44 Sc-DOTANOC. Results The optimized chemical separation method yielded up to 2 GBq 44 Sc of high radionuclidic purity. In the presence of gentisic acid, radiolabeling of 44 Sc with DOTANOC was achieved with a radiochemical yield of ~ 99% at high specific activity (10 MBq/nmol) and quantities which would allow clinical application. The dynamic PET images visualized increasing uptake of 44 Sc-DOTANOC into AR42J tumors and excretion of radioactivity through the kidneys of the investigated mouse. Conclusions The concept “from-bench-to-bedside” was clearly demonstrated in this extended study using cyclotron-produced 44 Sc. Sufficiently high activities of 44 Sc of excellent radionuclidic purity are obtainable for clinical application, by irradiation of enriched calcium at a cyclotron. This work demonstrates a promising basis for introducing 44 Sc to clinical routine of nuclear imaging using PET. [ABSTRACT FROM AUTHOR]