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1. Iron‐Catalyzed C( sp ² )−C( sp ³ ) Cross‐Coupling of Chlorobenzamides with Alkyl Grignard Reagents: Development of Catalyst System, Synthetic Scope, and Application

   https://doi.org/10.1002/adsc.201800849  

   Bisz, Elwira; Szostak, Michal (November 2018, Advanced Synthesis & Catalysis)

   Abstract Direct preparation of alkylated amide‐derivatives by cross‐coupling chemistry using sustainable protocols is challenging due to sensitivity of the amide functional group to reaction conditions. Herein, we report the synthesis of alkyl‐substituted amides by iron‐catalyzed C(sp²)−C(sp³) cross‐coupling of Grignard reagents with aryl chlorides. The products of these reactions are broadly used in the synthesis of pharmaceuticals, agrochemicals and other biologically‐active molecules. Furthermore, amides are used as versatile intermediates that can participate in the synthesis of valuable ketones and amines, providing access to motifs of broad synthetic interest. The reaction is characterized by its good substrate scope, tolerating a range of amide substitution, including sterically‐bulky, sensitive and readily modifiable amides. The reaction is compatible with challenging organometallics possessing β‐hydrogens, and proceeds under very mild, operationally‐simple conditions. Optimization of the catalyst system demonstrated the beneficial effect of O‐coordinating ligands on the cross‐coupling. The reaction was found to be fully chemoselective for the mono‐substitution at the less sterically‐hindered position. Mechanistic studies establish the order of reactivity and provide insight into the role of amide to control mono‐selectivity of the alkylation. The protocol provides the possibility for convenient access to alkyl‐amide structural building blocks using sustainable cross‐coupling conditions with high efficiency. magnified image 

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2. Transamidation of N-acyl-glutarimides with amines

   Liu, Yongmei; Achtenhagen, Marcel; Liu, Ruzhang; Szostak, Michal (February 2018, Organic & biomolecular chemistry)

   The development of new transamidation reactions for the synthesis of amides is an important and active area of research due to the central role of amide linkage in various fields of chemistry. Herein, we report a new method for transamidation of N-acyl-glutarimides with amines under mild, metal-free conditions that relies on amide bond twist to weaken amidic resonance. A wide range of amines and functional groups, including electrophilic substituents that would be problematic in metal-catalyzed protocols, are tolerated under the reaction conditions. Mechanistic experiments implicate the amide bond twist, thermodynamic stability of the tetrahedral intermediate and leaving group ability of glutarimide as factors controlling the reactivity of this process. The method further establishes the synthetic utility of N-acyl-glutarimides as bench-stable, twist-perpendicular, amide-based reagents in acyl-transfer reactions by a metal-free pathway. The origin of reactivity of N-acyl-glutarimides in metal-free and metal-catalyzed processes is discussed and compared. 

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3. Diastereoselective Synthesis of (3R,5R)-γ-Hydroxypiperazic Acid

   https://doi.org/10.1055/s-0040-1719824  

   Gerrein, Taylor A.; Elbatrawi, Yassin M.; Del Valle, Juan R. (October 2021, Synlett)

   Abstract We report an asymmetric synthesis of the (3R,5R)-γ-hydroxypiperazic acid (γ-OHPiz) residue encountered in several bioactive nonribosomal peptides. Our strategy relies on a diastereoselective enolate hydroxylation reaction and electrophilic N-amination to provide the acyclic γ-OHPiz precursor. This orthogonally protected α-hydrazino acid intermediate is amenable to late-stage diazinane ring formation following incorporation into a peptide chain. We determined the N-terminal amide rotamer propensity of the γ-OHPiz residue and showed that the γ-OH substituent enhances trans-amide bias relative to piperazic acid. 

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4. Cascade Reactions of Alkynyl Ketones and Amides to Generate Unsaturated Oxacycles and Aromatic Carbocycles

   https://doi.org/10.1002/chem.202403270  

   Rajapaksa, Kumudi_J_W; Yan_Wong, Hang; Lee, Daesung (November 2024, Chemistry – A European Journal)

   Abstract We describe novel amine‐mediated transformation of alkynyl ketones and amides to generate 2‐methylene‐2H‐pyrans, substituted 3‐hydroxy‐9H‐fluoren‐9‐ones, and amine‐incorporated arenes. These cascade processes are initiated by conjugate addition of secondary amine followed by hydrolysis of the enamine/vinylogous amide intermediates. The product distribution is highly sensitive to the steric and electronic effects of the substituents on both the alkyne moieties, the tether structure connecting them, and the nature of the amine. Alkynyl amide participates in the Alder‐ene reaction favorably to generate more reactive allene amide that reacts with amine to generate amine‐incorporated arene products. These metal‐free cascade reactions are a useful synthetic method that can be exploited for the construction of various hetero‐ and carbocyclic systems. 

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5. Dehydrogenative Conversions of Aldehydes and Amines to Amides Catalyzed by a Nickel(II) Pincer Complex

   https://doi.org/10.3390/catal13111423  

   Szwedo, Peter; Jumper, Travis; Sanford, Karie; Arnold, Taylor; Coffman, Sarah; Hokes, Davonte; Munshi, Pradip; Walker, Brian; Ghosh, Anindya (November 2023, Catalysts)

   A C-N cross-coupling approach involving oxidative amidations of aromatic aldehydes in the presence of an amide-based nickel(II) pincer catalyst (2) is demonstrated. Upon optimization, quick reaction times (15 min) and an ideal temperature (25 °C) were established and implemented for the conversion of 33 different amide products using only 0.2 mol% of catalyst. Moderate to good turnover numbers (TONs) were obtained for secondary benzamide products, and moderate TONs were obtained for tertiary benzamide products, with the highest turnover number calculated for the 4-chloro-N-(3-phenylpropyl)benzamide product (4i, 309). Gas chromatographic–mass spectrometric (GC–MS) analysis also indicates the formation of alcohols in different reactions, indicating an oxidative amidation process. Kinetic studies were performed by varying the amount of catalyst, aldehyde, LiHMDS base, and amine substrate to determine the order of reaction for each component. Benzaldehyde and benzaldehyde-d6 were reacted with benzylamine, and the kH/kD ratio was determined to understand the rate-determining step. Isotope labeling further revealed that deuterium was being transferred to both the alcohol side product and the target amide product. With the help of kinetic data and UV–visible spectra, a mechanism for the amidation process via the catalyst (2) is proposed through a Ni(I)–Ni(III) pathway. 

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