Calix[4]crowns with perfluoroalkylsulfonylcarboxamide functions: a complexation approach for heavy group 2 metal ions

Heavy alkaline earth metals offer radionuclides which are promising candidates for radiopharmaceutical applications like the gamma-emitter barium-131 for diagnosis or the alpha-emitters radium-223/-224 - with similar chemical properties to barium - for targeted alpha-particle therapy. However, there is a lack of suitable chelation agents, especially for these metal ions. A series of calix[4]crown-6 derivatives with perfluoroalkylsulfonylcarboxamide functions (R-F = CF3, C2F5, i-C3F7, n-C4F9) was synthesized to serve as cage-like chelators for Ba2+ and Ra2+ to determine the complexation behaviour. These functional ligands are deprotonated even at slightly acidic pH due to the intense electron-withdrawing effect of the sulfonamide groups. The obtained ligands were easily converted to the desired barium complexes as well as into calix-crown compounds containing two sodium ions. DFT calculations were used to discover the binding behaviour of the metal ions with the desired ligands and the influence of the different donor groups from the chelating moiety of the calixarenes with respect to different pH. Radiolabeling procedures with the radionuclides barium-133 and radium-224 as [Ba-133]BaCl2 and [Ra-224]Ra(NO3)(2) were performed to determine association constant values between 4.1 and 8.2 for the appropriate M2+ complexes using a two-phase extraction procedure. A stability test using physiological Ca2+ solution showed a minor release of approx. 1-7% of the central ions (Ba2+ respectively Ra2+) from the complexes.

Automated summary

Heavy alkaline earth metals, such as barium and radium, have potential applications in radiopharmaceuticals, including diagnosis and targeted therapy. However, there is a lack of suitable chelation agents for these metals. In this study, a series of calix[4]crown-6 derivatives were synthesized as chelators for barium and radium, and their complexation behavior was investigated. The obtained ligands were successfully converted into the desired barium complexes and calix-crown compounds containing sodium ions. DFT calculations and radiolabeling procedures were performed to determine the binding behavior and stability of the complexes.