Abstract
Studies on a one-pot synthesis of novel multisubstituted 1-alkoxyindoles 1 and their mechanistic investigations are presented. The synthesis of 1 was successfully achieved through consecutive four step reactions from substrates 2. The substrates 2, prepared through a two-step synthetic sequence, underwent three consecutive reactions of nitro reduction, intramolecular condensation, and nucleophilic 1,5-addition to provide the intermediates, 1-hydroxyindoles 8, which then were alkylated in situ with alkyl halide to afford the novel target products 1. We optimized the reaction conditions for 1 focusing on the alkylation step, along with the consideration of formation of intermediates 8. The optimized condition was SnCl2·2H2O (3.3 eq) and alcohols (R1OH, 2.0 eq) for 1–2 h at 40 °C and then, base (10 eq) and alkyl halides (R2Y, 2.0 eq) for 1–4 h at 25–50 °C. Notably, all four step reactions were performed in one-pot to give 1 in good to modest yields. Furthermore, the mechanistic aspects were also discussed regarding the reaction pathways and the formation of side products. The significance lies in development of efficient one-pot reactions and in generation of new 1-alkoxyindoles.
Highlights
Studies on a one-pot synthesis of novel multisubstituted 1-alkoxyindoles 1 and their mechanistic investigations are presented
We aimed to design and synthesize the compoun stability compared to 1-hydroxyindoles, with developing tolera is believed that an alkyl or acyl group directly connected to the i
Nitrotoluenes 3 were reacted with sodium were treated with sodium hydride and dimethylmethyleneiminium chloride in tetrahy hydride and dimethyl oxalate in the N,N-dimethylformamide (DMF) solvent to afford drofuran (THF)
Summary
Studies on a one-pot synthesis of novel multisubstituted 1-alkoxyindoles 1 and their mechanistic investigations are presented. The substrates 2, prepared through a two-step synthetic sequence, underwent three consecutive reactions of nitro reduction, intramolecular condensation, and nucleophilic 1,5-addition to provide the intermediates, 1-hydroxyindoles 8, which were alkylated in situ with alkyl halide to afford the novel target products 1. N-alkoxyindole-3-carbinol (I3C) compounds are proved to regulate cell cycle-related gene transcription and as a result exhibit inhibitory activities in human breast cancer cell lines [7]. Despite these biological activities of natural and synthetic products containing 1-hydroxyindole and 1-alkoxyindole structures, their derivatizations have not been extensively studied due to the lack of tolerable synthetic methods and the instability of those compounds
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