Synthesis of the cis- and trans-3-Fluoro Analogues of Febrifugine and Halofuginone

Abstract

The novel synthesis of racemic cis- and trans-3-fluorofebrifugine and halofuginone is described. This straight-forward seven-step process relies on an electrophilic fluorination-allylation sequence that generates a mixture of N-Cbz protected, diastereomeric 2-allyl-3-fluoropiperidines. On separation, a Wacker oxidation-methyl functionalisation sequence enabled introduction of the required quinazolinone portion. Finally, removal of the N-Cbz protecting group lead to isolation of the 3-fluorofebrifugine dihydrobromide analogues that are of potentially pharmacological use. Analysis of the NMR spectra for each stereoisomer provides information concerning the preferred conformers of the different diastereomers. Evidence indicates that the cis-diastereomer favours a conformation where the F-atom occupies an axial orientation. In contrast, for its trans-stereoisomeric counterpart, the 2-substituent overrides any F-atom effect and it preferentially occupies a conformer where both substituents occupy equatorial positions. Finally, interconversion between the cis- and trans-diastereomers was studied. In DMSO-d6 and as their free-bases, isomerisation of each diastereomer gave a common 65 : 35 ratio of trans- to cis-3-fluorofebrifugine. Determination of the reaction rate constants for the isomerisation process at different temperatures enabled calculation of the activation energy barriers, for each process, using an Arrhenius plot. The activation energy barrier for the isomerisation of the trans-isomer was 94.3±4.9 kJ mol−1, whereas for the cis-isomer it was 84.5±3.9 kJ mol−1.