Scale-up of Sodium Persulfate Mediated, Nitroxide Catalyzed Oxidative Functionalization Reactions.

IF 1.7 4区化学 Q3 CHEMISTRY, ORGANIC Current organic synthesis Pub Date : 2024-01-01 DOI:10.2174/1570179421666230831105337

Katrina E Doherty, Arturo L Sandoval, Fabrizio Politano, Mason L Witko, Chelsea M Schroeder, William P Brydon, Geoffrey P Wadey, Kristiane K Ohlhorst, Nicholas E Leadbeater

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Abstract

Background: Oxidation is a valuable tool in preparative organic chemistry. Oxoammonium salts and nitroxides have proven valuable as reagents and catalysts in this endeavor.

Objective: The objective of this study is to scale up the oxidative amidation, ester formation, and nitrile formation using nitroxide as an organocatalyst.

Methods: Oxidative functionalization reactions were scaled from the 1 mmol to the 1 mole level. Sodium persulfate was used as the primary oxidant, and a nitroxide was employed as a catalyst. The products of the reactions were isolated in analytically pure form by extraction with no need for column chromatography.

Results: The oxidative amidation and esterification of aldehydes can be scaled up from 1 mmol to 1 mole effectively, with comparable product yields being obtained at each increment. This work shows that conditions developed on a small scale can be transferred to a larger scale without reoptimization. The oxidative functionalization of aldehydes to prepare nitriles is not amenable to direct scale-up due to the concomitant formation of significant quantities of the corresponding carboxylic acid, thereby compromising the product yield.

Conclusion: Two of the three oxidative transformations studied here can be scaled up successfully from the 1 mmol to the 1 mole level.

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过硫酸钠介导、氧化亚氮催化的氧化官能化反应的放大。

背景：氧化是制备有机化学的重要工具。氧化铵盐和亚硝基氧化物已被证明是这一领域的重要试剂和催化剂：本研究的目的是利用亚硝基氧化物作为有机催化剂，扩大氧化酰胺化、酯化和腈化反应的规模：氧化官能化反应从 1 毫摩尔放大到 1 摩尔水平。过硫酸钠被用作主氧化剂，而亚硝基氧化物被用作催化剂。反应产物通过萃取以分析纯的形式分离出来，无需柱层析：结果：醛的氧化酰胺化和酯化反应可以有效地从 1 毫摩尔放大到 1 摩尔，而且每次放大都能获得相当的产物产量。这项工作表明，在小规模上开发的条件无需重新优化即可转移到更大规模上。醛的氧化官能化制备腈不适合直接放大，因为会同时生成大量相应的羧酸，从而影响产品收率：结论：本文研究的三种氧化转化中，有两种可以成功地从 1 毫摩尔放大到 1 摩尔水平。

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来源期刊

Current organic synthesis 化学-有机化学

CiteScore

3.40

自引率

5.60%

发文量

审稿时长

6-12 weeks

期刊介绍： Current Organic Synthesis publishes in-depth reviews, original research articles and letter/short communications on all areas of synthetic organic chemistry i.e. asymmetric synthesis, organometallic chemistry, novel synthetic approaches to complex organic molecules, carbohydrates, polymers, protein chemistry, DNA chemistry, supramolecular chemistry, molecular recognition and new synthetic methods in organic chemistry. The frontier reviews provide the current state of knowledge in these fields and are written by experts who are internationally known for their eminent research contributions. The journal is essential reading to all synthetic organic chemists. Current Organic Synthesis should prove to be of great interest to synthetic chemists in academia and industry who wish to keep abreast with recent developments in key fields of organic synthesis.