A new automated and putatively versatile synthesis of the PSMA-ligand derivative [F]DCFPyL using the FASTlab synthesizer.

Background: Noninvasive molecular imaging using peptides and biomolecules labelled with positron emitters has become important for detection of cancer and other diseases with PET (positron emission tomography). The positron emitting radionuclide fluorine-18 is widely available in high yield from cyclotrons and has favorable decay (t 109.7 min) and imaging properties.

Preparation of [18F]-N-(2-fluoro-ethyl)-N-methylamine as a building block for PET radiopharmaceuticals.

We have investigated the use of cyclic sulfamidates as precursors to yield secondary amines as building blocks for subsequent reaction with carboxylic acids and acyl chlorides. The preparation of the protonated form of [(18)F]-N-(2-fluoro-ethyl)-N-methylamine from the corresponding cyclic sulfamidate proceeded within a one pot two-step procedure (81 ± 12%, n = 10). The secondary amine reacted readily with acyl chlorides and/or carboxylic acids giving amides with yields ranging from 4 to 17% at the end of synthesis (182 ± 12 min).

Radiosyntheses using fluorine-18: the art and science of late stage fluorination.

Positron (β(+)) emission tomography (PET) is a powerful, noninvasive tool for the in vivo, three-dimensional imaging of physiological structures and biochemical pathways. The continued growth of PET imaging relies on a corresponding increase in access to radiopharmaceuticals (biologically active molecules labeled with short-lived radionuclides such as fluorine-18). This unique need to incorporate the short-lived fluorine-18 atom (t1/2 = 109.

Fully automated radiosynthesis of [¹¹C]PBR28, a radiopharmaceutical for the translocator protein (TSPO) 18 kDa, using a GE TRACERlab FXC-Pro.

In order to image the translocator protein (TSPO) 18kDa in the clinic using positron emission tomography (PET) imaging, we had a cause to prepare [(11)C]PBR28. In this communication we highlight our novel, recently developed, one-pot synthesis of the desmethyl-PBR28 precursor, as well as present an optimized fully automated preparation of [(11)C]PBR28 using a GE TRACERlab FX(C-Pro). Following radiolabelling, purification is achieved by HPLC and, to the best of our knowledge, the first reported example of reconstituting [(11)C]PBR28 into ethanolic saline using solid-phase extraction (SPE).

Highlighting the Versatility of the Tracerlab Synthesis Modules. Part 1: Fully Automated Production of [F]Labelled Radiopharmaceuticals using a Tracerlab FX(FN).

The field of radiochemistry is moving towards exclusive use of automated synthesis modules for production of clinical radiopharmaceutical doses. Such a move comes with many advantages, but also presents radiochemists with the challenge of re-configuring synthesis modules for production of radiopharmaceuticals that require non-conventional radiochemistry whilst maintaining full automation. This review showcases the versatility of the Tracerlab FX(FN) synthesis module by presenting simple, fully automated methods for producing [(18)F]FLT, [(18)F]FAZA, [(18)F]MPPF, [(18)F]FEOBV, [(18)F]sodium fluoride, [(18)F]fluorocholine and [(18)F]SFB.

Fully automated preparation of [11C]choline and [18F]fluoromethylcholine using TracerLab synthesis modules and facilitated quality control using analytical HPLC.

Modifications of a GE TracerLab FX(C-Pro), which can be implemented for solid-phase [(11)C]methylation are described. The simplified procedure for synthesis of [(11)C]choline uses a single Sep-Pak CM-Light cation-exchange cartridge for both solid-supported reaction and purification. Compared with the commonly used two Sep-Pak method, the low back-pressure of this Sep-Pak enables efficient and reliable production of [(11)C]choline using a TracerLab FX(C-Pro) without requirement for any gas pressure adjustment.