Multistep Synthesis of Paracetamol in Continuous Flow

Pharmaceutical Fronts Pub Date : 2023-07-15 DOI:10.1055/s-0043-1772252

Jian-li Chen, Jing-Yu Hu, Qi-Fan Wang, Peng Ge, Quan-Hui Wang, Zi-Shuo Lou

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Abstract

p-Aminophenol (AP) is the key intermediate of the traditional synthesis of paracetamol. The method of obtaining AP included a selective reduction reaction of the generation of N-arylhydroxylamine (AHA) using nitrobenzene (NB) as the raw material, followed by a Bamberger rearrangement reaction to transfer AHA to the target product. The generation of AHA is a key step, but due to its structural instability and the incompatibility of the two reaction systems, one-pot synthesis of paracetamol faces great challenges. Considering that using flow reactors in series may avoid the problems faced by batch reactors, the article presents the strategy to obtain paracetamol via a continuous flow technology. In particular, we focus on condition screening in total synthesis experiments, including hydrogenation, Bamberger rearrangement, and amidation in flow. The continuous three-step synthesis process used NB as a raw material to generate AHA, which entered the downstream for timely conversion, achieving in situ on-demand preparation of the unstable intermediate AHA, avoiding cumbersome processing and storage processes. Moreover, each step of the reaction system exhibits excellent compatibility, and the work-up is simple.

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连续流法多步合成扑热息痛

对氨基酚(AP)是传统合成扑热息痛的关键中间体。AP的制备方法包括以硝基苯(NB)为原料，通过选择性还原反应生成n -芳基羟胺(AHA)，然后通过班贝格重排反应将AHA转移到目标产物。AHA的生成是关键的一步，但由于其结构的不稳定性和两种反应体系的不相容性，一锅法合成扑热息痛面临着很大的挑战。考虑到采用串联流动反应器可以避免间歇式反应器所面临的问题，本文提出了采用连续流动技术制备扑热息痛的策略。我们特别关注全合成实验的条件筛选，包括氢化、班贝格重排和流动酰胺化。连续三步合成工艺以NB为原料生成AHA，进入下游及时转化，实现了不稳定中间体AHA的原位按需制备，避免了繁琐的加工和储存过程。此外，反应体系的每一步都表现出良好的相容性，后处理简单。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Pharmaceutical Fronts

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15 weeks