Porphyrins with exocyclic rings. Part 24. Synthesis and spectroscopic properties of pyrenoporphyrins, potential building blocks for porphyrin molecular wires

Porphyrins with fused pyrene units have been prepared by ‘2+2’ and ‘3+1’ methodologies. Nitration of 1,2,3,6,7,8-tetrahydropyrene, followed by oxidation with DDQ, gave 4-nitropyrene and this condensed with ethyl isocyanoacetate in the presence of DBU or a phosphazene base to generate a pyrenopyrrole ethyl ester. Ester saponification and decarboxylation with KOH in ethylene glycol at 190 °C gave the parent pyreno[4,5-c]pyrrole and this was further condensed with 2 equiv of acetoxymethylpyrroles to afford the corresponding tripyrranes protected at the terminal positions with tert-butyl esters. In a one pot procedure, the ester protective groups were cleaved with TFA and following dilution with dichloromethane, ‘3+1’ condensation with a pyrrole dialdehyde, and dehydrogenation with DDQ, the targeted pyrenoporphyrins were generated in good overall yields. A dialdehyde was also prepared from the pyrenopyrrole intermediate and this reacted to give an opp-dipyrenoporphyrin. The pyrenopyrrole ethyl ester reacted with dimethoxymethane in the presence of an acid catalyst to give a dipyrenopyrrolylmethane, and this was used to prepare an adj-dipyrenoporphyrin using the MacDonald ‘2+2’ approach. The pyrenopyrrole dialdehyde was also used to prepare a porphyrin with fused pyrene and phenanthroline moieties. Although the UV-vis spectra of these new porphyrin systems are unexceptional, pyrenoporphyrins show many of the features necessary for the construction of porphyrin molecular wires.