Phosphonate-Based Aza-Macrocycle Ligands for Low-Temperature, Stable Chelation of Medicinally Relevant Rare Earth Radiometals and Radiofluorination.

Radioisotopes of fluorine (F), scandium (Sc, Sc), lutetium (Lu), and yttrium (Y, Y) have decay properties ideally suited for targeted nuclear imaging and therapy with small biologics, such as peptides and antibody fragments. However, a single-molecule strategy to introduce these radionuclides into radiopharmaceuticals under mild conditions to afford inert in vivo complexes is critically lacking. Here, we introduce HL2 and HL3, two small-cavity macrocyclic chelator structural isomers bearing a single phosphonate functional group.

Charting the coordinative landscape of the F-Sc/Sc/Lu triad with the tri-aza-cyclononane (tacn) scaffold.

The widely established PET isotope F does not have a therapeutic partner. We have recently established that the Sc-F bond can be formed under aqueous, high yielding conditions, paving the way to providing F as diagnostic partners to Sc and Lu radiotherapeutics. Here, we synthesized a library of tacn-based chelators comprised of 10 structurally unique permutations incorporating acetate, methyl-benzylamide and picolinate donor arms.

"Off-Label Use" of the Siderophore Enterobactin Enables Targeted Imaging of Cancer with Radioactive Ti.

The development of inert, biocompatible chelation methods is required to harness the emerging positron emitting radionuclide Ti for radiopharmaceutical applications. Herein, we evaluate the Ti-coordination chemistry of four catechol-based, hexacoordinate chelators using synthetic, structural, computational, and radiochemical approaches. The siderophore enterobactin (Ent) and its synthetic mimic TREN-CAM readily form mononuclear Ti species in aqueous solution at neutral pH.

De Novo Approaches to the Solid-Phase Separation of Titanium(IV) and Scandium(III): Translating Speciation Data to Selective On-Bead Chelation toward Applications in Nuclear Medicine.

The solution chemistry of the hydrolytic, early-transition-metal ions Ti and Sc represents a coordination chemistry challenge with important real-world implications, specifically in the context of Ti/Sc and Ti/Sc radiochemical separations. Unclear speciation of the solid and solution phases and tertiary mixtures of mineral acid, organic chelators, and solid supports are common confounds, necessitating tedious screening of multiple variables. Herein we describe how thermodynamic speciation data in solution informs the design of new solid-phase chelation approaches enabling separations of Ti and Sc.