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Relevant academic research and scientific papers

Electrochemical Synthesis of α-Ketoamides under Catalyst-, Oxidant-, and Electrolyte-Free Conditions

A catalyst-, oxidant-, electrolyte-free method for the preparation of α-ketoamides through the direct electrochemical amidation of α-ketoaldehydes and amines with innocuous hydrogen as the sole byproduct at ambient temperature was developed. The present reaction features clean and mild conditions, excellent functional-group tolerance, and high atom economy and scalability, enabling facile applications in pharmaceutical chemistry.

Preparation method of alpha-carbonyl amide compound

The invention discloses a preparation method of an alpha-carbonyl amide compound. The method comprises the following steps: under the action of a catalyst, taking oxygen as an oxidant, and carrying out oxidative amidation reaction on an alpha-diazoketone compound shown in a chemical formula 2 and a cyclic secondary amine compound shown in a chemical formula 3 in an organic solvent to obtain the alpha-carbonyl amide compound shown in a chemical formula 1, wherein the formulas 1, 2 and 3 are also shown in the speification. According to the preparation method disclosed by the invention, the alpha-carbonyl amide compound is obtained by taking oxygen as the oxidizing agent and catalyzing alpha-diazoketone and cyclic secondary amine to be subjected to oxidative amidation reaction through cuprous iodide, the reaction condition is mild, the reaction time is short, and the byproduct of the reaction is only nitrogen, so that the method is an effective way for green and efficient preparation of the alpha-carbonyl amide compound.

Synthesis of aliphatic α-ketoamides from α-substituted methyl ketones: Via a Cu-catalyzed aerobic oxidative amidation

α-Ketoamides are an important key functional group and have been used as versatile and valuable intermediates and synthons in a variety of functional group transformations. Synthetic methods for making aryl α-ketoamides as drug candidates have been greatly improved through metal-catalyzed aerobic oxidative amidations. However, the preparation of alkyl α-ketoamides through metal-catalyzed aerobic oxidative amidations has not been reported because generating α-ketoamides from aliphatic ketones with two α-carbons theoretically provides two distinct α-ketoamides. Our strategy is to activate the α-carbon by introducing an N-substituent at one of the two α-positions. The key to this strategy is how heterocyclic compounds such as triazoles and imidazoles affect the selectivity of the synthesis of the alkyl α-ketoamides. From this basic concept, and by optimizing the reaction and elucidating the mechanism of the synthesis of aryl α-ketoamides via a copper-catalyzed aerobic oxidative amidation, we prepared fourteen aliphatic α-ketoamides in high yields (48-84%). This journal is

Visible-Light Mediated Photooxidative Synthesis of α-Keto Amides

Photocatalytic amidation of α-keto aldehydes is herein investigated. This transformation was achieved using rose bengal as photocatalyst at room temperature under ambient air and under irradiation of a 20 W white LED bulb. The method is mild, efficient an

One pot synthesis of α-ketoamides from ethylarenes and amines: a metal free difunctionalization strategy

One-pot and metal free synthesis of α-ketoamides has been described through in situ generation of aryl ketones from easily available ethylarenes followed by amidation with various amines. This multiple oxidation protocol involves catalytic I2-pyridine-TBHP (t-butyl hydroperoxide) mediated oxidative benzylic carbonylation and sequential NaI-TBHP mediated oxidative amidation without using any solvent.

Selenium dioxide-mediated synthesis of α-ketoamides from arylglyoxals and secondary amines

A facile and expeditious synthetic approach for the synthesis of α-ketoamides 3 is described. A series of α-ketoamides 3 was synthesized via reaction of selenium dioxide-mediated oxidative amidation between arylglyoxals 1 and secondary amines 2, and accelerated with microwave irradiation. Our findings indicate that constrained amines, such as piperazine and piperidine exhibit higher conversions for this transformation. This reaction was explored by synthesizing a series of α-ketoamides 3 from various arylglyoxals 1 with cyclic and acyclic secondary amines 2.