Dana Nemeckova-Herova and Pavel Pazdera Pages 173 - 179 ( 7 )
We report a simplified protocol for the routine direct chemoselective preparation of various piperazines substituted in the 1-position by an electron withdrawing group. These syntheses are based on the reaction of piperazine-1- ium cation with different electrophilic reagents such as acyl chlorides, anhydrides, sulfonyl chlorides, carbamoyl chlorides, and nitrourea as well. Piperazine-1-ium cation was chosen because the reactions of piperazine with electrophilic reagents in different solvents at usual temperatures are not chemoselective and provide mixtures comprising 1- substituted, 1,4-disubstituted and unsubstituted piperazine as well. Simultaneously, the mono-protonation of piperazine is the simplest synthetic method for its protection/deprotection in comparison with the currently used mono-benzylation, mono-Boc-protection, etc. Computer modeling of acid-base equilibria for piperazine and model 1-acetylpiperazine was used as the basis for the prediction of reaction conditions suitable for the synthesis. It was found that for in situ generating of starting piperazine-1-ium cation from piperazine the application of acetic acid as reaction medium or the chemisorption of piperazine on weakly acidic cationexchanger resin were highly acceptable in terms of both reaction times and yields. The using of resin supported piperazine-1-ium cation in reaction with carboxylic anhydrides or nitrourea is an example of the solid phase synthesis with ionically bonded substrate. Furthermore, syntheses in acetic acid medium were effectively catalyzed by Cu+, Cu2+ or Al3+ ions supported on weakly acidic cation-exchanger resin as well. Finally, it was observed that application of the solid support metal catalysis afforded target products in shortened reaction times and in 82-95% yields.
1-monosubstituted piperazine, ionically-bound substrate, metal catalysis, piperazine, piperazine-1-ium cation, resin supported metal ion, solid phase synthesis.
Centre for syntheses at sustainable conditions and their management, Chemistry Department, Masaryk University, Kamenice 5, Brno, 625 00, Czech Republic.