Development of a Scalable Route for a Key Thiadiazole Building Block via Sequential Sandmeyer Bromination and Room-Temperature Suzuki–Miyaura Coupling

IF 3.1 3区化学 Q2 CHEMISTRY, APPLIED

Organic Process Research & Development Pub Date : 2020-01-28 DOI:10.1021/acs.oprd.9b00495

Gabriel Schäfer*, Tony Fleischer, Muhamed Ahmetovic, Stefan Abele

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引用次数: 9

Abstract

To avoid the use and handling of Lawesson’s reagent or other thiation agents in the in-house kilolab, a new scalable route to ethyl 5-(2,4-difluorophenyl)-1,3,4-thiadiazole-2-carboxylate (1) was developed. The key to success was the use of a commercially available amino-thiadiazole building block, which was converted into the desired product via a sequence of Sandmeyer bromination and Suzuki–Miyaura coupling. The different parameters of the Pd-catalyzed coupling have been studied in detail and allowed the reaction to be performed under mild conditions at room temperature and with low catalyst loading. The inconsistencies of the initial scale-up runs with regard to the sluggish conversion of the Suzuki–Miyaura coupling due to Cu contamination were addressed, and the findings were directly implemented in the subsequent batches, which finally led to an improved overall understanding and robustness of the process.

Abstract Image

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通过顺序Sandmeyer溴化和室温Suzuki-Miyaura偶联的关键噻二唑构建块的可扩展路线的开发

为了避免在内部实验室中使用Lawesson试剂或其他硫代试剂，开发了一种新的可扩展路线，以获得5-(2,4-二氟苯基)-1,3,4-噻二唑-2-羧酸乙酯(1)。成功的关键是使用了市售的氨基噻二唑构建块，通过一系列Sandmeyer溴化和Suzuki-Miyaura偶联将其转化为所需的产品。对钯催化偶联的不同参数进行了详细的研究，使反应在室温和低催化剂负载的温和条件下进行。由于Cu污染导致的Suzuki-Miyaura耦合转化缓慢的初始放大运行的不一致性得到了解决，并且研究结果直接应用于后续批次，最终提高了对该过程的整体理解和鲁棒性。

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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来源期刊

Organic Process Research & Development 化学-应用化学

CiteScore

6.90

自引率

14.70%

发文量

251

审稿时长

2 months

期刊介绍： The journal Organic Process Research & Development serves as a communication tool between industrial chemists and chemists working in universities and research institutes. As such, it reports original work from the broad field of industrial process chemistry but also presents academic results that are relevant, or potentially relevant, to industrial applications. Process chemistry is the science that enables the safe, environmentally benign and ultimately economical manufacturing of organic compounds that are required in larger amounts to help address the needs of society. Consequently, the Journal encompasses every aspect of organic chemistry, including all aspects of catalysis, synthetic methodology development and synthetic strategy exploration, but also includes aspects from analytical and solid-state chemistry and chemical engineering, such as work-up tools，process safety, or flow-chemistry. The goal of development and optimization of chemical reactions and processes is their transfer to a larger scale; original work describing such studies and the actual implementation on scale is highly relevant to the journal. However, studies on new developments from either industry, research institutes or academia that have not yet been demonstrated on scale, but where an industrial utility can be expected and where the study has addressed important prerequisites for a scale-up and has given confidence into the reliability and practicality of the chemistry, also serve the mission of OPR&D as a communication tool between the different contributors to the field.