Ben Chalmers

The methoxyamine group represents an ideal protecting group for the nitroxide moiety. It can be easily and selectively introduced in high yield (typically >90%) to a range of functionalised nitroxides using FeSO4·7H2O and H2O2 in DMSO. Its removal is readily achieved under mild conditions in high yield (70–90%) using mCPBA in a Cope-type elimination process.

The robust and diversely useful isoindoline nitroxide, 5-carboxy-1,1,3,3-tetramethylisoindolin-2-yloxyl (1; CTMIO), has previously been synthesised in low-to-moderate yields from phthalic anhydride (3). Recent interest in its biological potential as a potent antioxidant and in other areas has seen an increased demand for its production. Herein, three new synthetic routes to CTMIO are presented and their efficiencies assessed. Two routes, via the nitrile 9 and the formyl compound 11, derive from 5-bromo-1,1,3,3-tetramethylisoindoline (6). The third approach starts from the readily accessible starting material, 4-methylphthalic anhydride (12), and proceeds by a methylarene oxidation with potassium permanganate. The three new approaches yield CTMIO in comparable overall yields (16–18 %); however, the synthetic efficiency is most improved when employing the nitrile intermediate 9.

We describe a novel and facile approach to covalently graft molecules containing stable free radicals onto carbon surfaces including graphene, carbon nanotubes, glassy carbon and carbon fibres. The new technique employs a stable aryl nitroxide radical diazonium tetrafluoroborate salt. The salt may be isolated and added to carbon surfaces in solution, suspension or electrochemically and represents a convenient, versatile and highly efficient means to adorn graphitic materials with large numbers of free radical spin systems.

We have recently developed a simple, yet highly effective protecting group strategy to facilitate the synthesis of highly functionalised nitroxide free radicals. We have determined that the methoxyamine group represents an ideal protecting group for the free radical of the nitroxide moiety. The methoxyamine group can be easily and selectively introduced in high yield (typically >90%) to a range of functionalised nitroxides. Previously difficult transformations, such as metalation, may then be performed on these intermediates. Removal of the protecting group is readily achieved under mild conditions in high yield (70-90%) using mCPBA in a Cope-type
elimination process. Herein we describe the application of this method in the presence of various functional groups, the proposed mechanisms involved, implementation to date and future applications for advanced synthesis.