Catalysis amides synthesis

Benkovic, S.J. Napper, A.D. and Lerner, R.A. Catalysis of stereospecific biomolecular amide synthesis by an antibody. Proc Natl Acad Sci USA 85 5355-5358, 1988. 

Chen C, Verpoort F, Wu Q (2016) Atom-eeonomie dehydrogenative amide synthesis via ruthenium catalysis. RSC Adv 6(60) 55599-55607... 

Primary phosphines (R-PHj) are an important ciass of compounds in organophosphorus chemistry. Aithough discovered over a century ago, their chemistry and appiications have gained prominence in recent years. This review discusses recent deveiopments on synthesis, moiecuiar structure, properties, and appiications of primary phosphines. In particular, discussions on synthesis and properties emphasize recent results from our laboratory on the chemical architecture of amide, thioether, and carboxylate functionalized primary bisphos-phines. The utility of bromo- and aminopropyl phosphines (X(CH2)3PH2 X=Br or NH2) as building blocks to produce designer primary phosphines that display exceptional oxidative stability is described. The review also discusses the utility of carboxylate functionalized primary phosphines for incorporation on to peptides and their potential applications in catalysis and biomedicine. 

Scheme 10.14 gives some other examples of Wolff rearrangement reactions. Entries 1 and 2 are reactions carried out under the classical silver ion catalysis conditions. Entry 3 is an example of a thermolysis. Entries 4 to 7 are ring contractions done under photolytic conditions. Entry 8, done using a silver catalyst, was a step in the synthesis of macbecin, an antitumor antibiotic. Entry 9, a step in the synthesis of a drug candidate, illustrates direct formation of an amide by trapping the ketene intermediate with an amine. 

The enantioselective hydrogenation of prochiral substances bearing an activated group, such as an ester, an acid or an amide, is often an important step in the industrial synthesis of fine and pharmaceutical products. In addition to the hydrogenation of /5-ketoesters into optically pure products with Raney nickel modified by tartaric acid [117], the asymmetric reduction of a-ketoesters on heterogeneous platinum catalysts modified by cinchona alkaloids (cinchonidine and cinchonine) was reported for the first time by Orito and coworkers [118-121]. Asymmetric catalysis on solid surfaces remains a very important research area for a better mechanistic understanding of the interaction between the substrate, the modifier and the catalyst [122-125], although excellent results in terms of enantiomeric excesses (up to 97%) have been obtained in the reduction of ethyl pyruvate under optimum reaction conditions with these Pt/cinchona systems [126-128],... 

The amidocarbonylation of aldehydes provides highly efficient access to N-acyl a-amino acid derivatives by the reaction of the ubiquitous and cheap starting materials aldehyde, amide, and carbon monoxide under transition metal-catalysis [1,2]. Wakamatsu serendipitously discovered this reaction when observing the formation of amino acid derivatives as by-products in the cobalt-catalyzed oxo reaction of acrylonitrile [3-5]. The reaction was further elaborated to an efficient cobalt- or palladium-catalyzed one-step synthesis of racemic N-acyl a-amino acids [6-8] (Scheme 1). Besides the range of direct applications, such as pharmaceuticals and detergents, racemic N-acetyl a-amino acids are important intermediates in the synthesis of enantiomeri-cally pure a-amino acids via enzymatic hydrolysis [9]. 

Additional work was carried out by the GE group on optimization of the reaction yield and to eliminate unwanted linear oligomers [14], Three side reactions which interfere with synthesis of cyclics were identified reaction of the amine with acid chloride to form an acyl ammonium salt, followed by decomposition to an amide (Equation (3.2)) reaction with CH2CI2 to form a salt (Equation (3.3)) hydrolysis of the acid chloride, forming carboxylate via catalysis... 

An important contribution was recently made by Inoue and co-workers (35) (eq. [4]). Using the chiral cyclic dipeptide cyclo(L-Phe-L-His) these authors obtained a better than 90% e.e. in the reaction of benzaldehyde with cyanide ion. The preparation of the enantiomeric unnatural dipeptide obviously poses far fewer problems than the synthesis of an enantiomeric enzyme. It appears that, at least in principle, optically pure cyanohydrins of the desired configuration are accessible via catalysis by chiral amines or amides. 

C-H activation remains an important topic for catalysis even after thirty years of intensive research. The potential shortcuts it offers for many present routes to a wide variety of chemicals that are produced will continue to inspire industrial and academic research [32], An interesting example involves the enantiospecific, coordination-directed C-H bond functionalisation in the synthesis of a natural product, rhazinilam, an anti-tumor agent. The resulting vinyl moiety obtained in the dehydrogenation was subsequently carbonylated to form a cyclic amide [33],... 

A very successful example for the use of dendritic polymeric supports in asymmetric synthesis was recently described by Breinbauer and Jacobsen [76]. PA-MAM-dendrimers with [Co(salen)]complexes were used for the hydrolytic kinetic resolution (HKR) of terminal epoxides. For such asymmetric ring opening reactions catalyzed by [Co(salen)]complexes, the proposed mechanism involves cooperative, bimetallic catalysis. For the study of this hypothesis, PAMAM dendrimers of different generation [G1-G3] were derivatized with a covalent salen Hgand through an amide bond (Fig. 7.22). The separation was achieved by precipitation and SEC. The catalytically active [Co "(salen)]dendrimer was subsequently obtained by quantitative oxidation with elemental iodine (Fig. 7.22). 

During the coverage period of this chapter, reviews have appeared on the following topics reactions of electrophiles with polyfluorinated alkenes, the mechanisms of intramolecular hydroacylation and hydrosilylation, Prins reaction (reviewed and redefined), synthesis of esters of /3-amino acids by Michael addition of amines and metal amides to esters of a,/3-unsaturated carboxylic acids," the 1,4-addition of benzotriazole-stabilized carbanions to Michael acceptors, control of asymmetry in Michael additions via the use of nucleophiles bearing chiral centres, a-unsaturated systems with the chirality at the y-position, and the presence of chiral ligands or other chiral mediators, syntheses of carbo- and hetero-cyclic compounds via Michael addition of enolates and activated phenols, respectively, to o ,jS-unsaturated nitriles, and transition metal catalysis of the Michael addition of 1,3-dicarbonyl compounds. ... 

However, perhaps the simplest route to quinazoline derivatives involves the heating of 2-aminobenzamides with formic acid to give 4(3//)-quinazolinones, where the formic acid provides the solvent, the C-2 synthon, and the acid catalysis of the ring-closure step. For example, in the synthesis of the imidazoquinazolinone 798, both the imidazo and pyrimidine rings were formed simply by heating the triamino amide 797 in formic acid for 2h <1996JME918>. 

Piperazine-2,5-diones can be symmetric or asymmetric. Symmetric DKPs are readily obtained by heating amino acid esters,1179-181 whereas asymmetric DKPs are obtained directly from the related dipeptides under basic or, more properly, acid catalysis, or by cyclocondensation of dipeptide esters.1182-185 As an alternative procedure hexafluoroacetone can be used to protect/activate the amino acid for the synthesis of symmetric DKPs or of the second amino acid residue for synthesis of the dipeptide ester and subsequent direct cyclocondensation to DKPs.1186 The use of active esters for the cyclocondensation is less appropriate since it may lead to epimerization when a chiral amino acid is involved as the carboxy component in the cyclization reaction. Resin-bound DKPs as scaffolds for further on-resin transformations are readily prepared using the backbone amide linker (BAL) approach, where the amino acid ester is attached to the BAL resin by its a-amino group and then acylated with a Fmoc-protected amino acid by the HATU procedure, N -deprotection leads to on-resin DKP formation1172 (see Section 6.8.3.2.2.3). 

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