Amines aldehydes or ketones

The Ugi reaction is the four-component condensation of an amine, aldehyde or ketone, carboxylic acid and isocyanide to give an o -acylamino amide [22-24], Although this process has the potential to introduce considerable diversity, the products themselves are not heterocycles but through appropriate choice of substrates, latent functionality in one of the precursors can intercept either an intermediate or further derivatize the acylamino amide Ugi product through post-modification. Thus variants of the Ugi reaction have been investigated under microwave-assisted conditions for the synthesis of diverse heterocyclic libraries [16,19-24],... 

Reductive amination aldehyde or ketone => amine (amine or ammonia, H2, Rh)... 

Seconcdary amine Aldehyde or ketone Carbinolamine Enamine... 

The practical difficulties sometimes encountered in Kabachnik-Medved -Fields syntheses of (a-aminoalkyl)phosphonic acids from amines, aldehydes or ketones, and dialkyl hydrogenphosphonates, have been traced to the rearrangement of dialkyl (1-hydrox-yalkyl)phosphonates to isomeric phosphate esters under the essentially basic conditions the reactions involved are summarized in Scheme 17. The direct conversion of a (hydrox-yalkyl)phosphonic diester into the corresponding (aminoalkyl)phosphonate by the action of the amine is known, generally, not to take place, and it seems much more likely that successful Kabachnik-Medved -Fields syntheses proceed by the addition of the hydro-... 

Ugi four-component coupling reaction, in which an amine, aldehyde or ketone, carboxylic acid and isocyanide react to yield an a-acylamino amide, was performed by Nielsen et al. on a solid polymer support under microwave irradiation... 

The Ugi Reaction is the one-pot condensation of an amine, aldehyde or ketone, isocyanide, and a nucleophile to afford a-substituted carboxamide derivatives. Also known as the Ugi Four-Component Reaction (U-4CR) or Ugi Four-Component Coupling (or Condensation) (U-4CC), this reaction is recognized as a reliable tool for the construction of peptide bonds and for its applications within combinatorial chemistry. ... 

Despite the chemical complexity of multicomponent reactions (MCRs), the dawn of MCRs was fairly early in the history of organic chemistry. The first MCR was the so-called Strecker reaction discovered in 1850 [1, 2], which generates amino acids via a three-component reactiOTi between amines, aldehydes (or ketones), and hydrogen cyanide (Scheme 1). Since then, organic chemists have devoted much effort to the discovery of additional MCRs. Thus, we now can find a number of MCRs, including the Biginelli reaction [3], the Gewald reaction [4], the van Leusen three-component reaction [5], the Hantzsch reaction [6], the Mannich reaction [7], the Kabachnik-Fields reaction [8, 9], the Passerini reaction [10], the Ugi reaction [11, 12] and numerous variations thereof [13]. 

Doebner-von Miller reaction Condensation of an aromatic amine with an aldehyde or ketone in the presence of hydrochloric acid to form a quinoline derivative. A general method, thus aniline and ethanal give 2-methyl-quinoline (quinaldine) and p-phenetidine. 

Lead(fV) ethanoate, Pb(02CCH3)4, (Pb(ll)ethanoate plus CI2) is a powerful oxidizing agent which will convert vicinal glycols to aldehydes or ketones and 1,2-dicarboxylic acids into alkenes. Primary amides give ketones and amines give nitriles. 

The conversion of an aldehyde or ketone into the corresponding amine by heating with ammonium formate or with formamide and formic acid at about... 

The condensation of aldehydes or ketones with secondary amines leads to "encunines via N-hemiacetals and immonium hydroxides, when the water is removed. In these conjugated systems electron density and nudeophilicity are largely transferred from the nitrogen to the a-carbon atom, and thus enamines are useful electroneutral d -reagents (G.A. Cook, 1969 S.F. Dyke, 1973). A bulky heterocyclic substituent supports regio- and stereoselective reactions. 

The first stage of the mechanism is exactly the same as for nucleophilic addition to the carbonyl group of an aldehyde or ketone Many of the same nucleophiles that add to aldehydes and ketones—water (Section 17 6) alcohols (Section 17 8) amines (Sections 17 10-17 11)—add to the carbonyl groups of carboxylic acid derivatives... 

For oximes, the word oxime is placed after the name of the aldehyde or ketone. If the carbonyl group is not the principal group, use the prefix hydroxyimino-. Compounds with the group Z = N—OR are named by a prefix alkyloxyimino- as oxime O-ethers or as O-substituted oximes. Compounds with the group r C=N(0)R are named by adding A-oxide after the name of the alkylideneaminc compound. For amine oxides, add the word oxide after the name of the base, with locants. For example, C5H5N—O is named pyridine A-oxide or pyridine 1-oxide. 

The zwitterion (6) can react with protic solvents to produce a variety of products. Reaction with water yields a transient hydroperoxy alcohol (10) that can dehydrate to a carboxyUc acid or spHt out H2O2 to form a carbonyl compound (aldehyde or ketone, R2CO). In alcohoHc media, the product is an isolable hydroperoxy ether (11) that can be hydrolyzed or reduced (with (CH O) or (CH2)2S) to a carbonyl compound. Reductive amination of (11) over Raney nickel produces amides and amines (64). Reaction of the zwitterion with a carboxyUc acid to form a hydroperoxy ester (12) is commercially important because it can be oxidized to other acids, RCOOH and R COOH. Reaction of zwitterion with HCN produces a-hydroxy nitriles that can be hydrolyzed to a-hydroxy carboxyUc acids. Carboxylates are obtained with H2O2/OH (65). The zwitterion can be reduced during the course of the reaction by tetracyanoethylene to produce its epoxide (66). 

With secondary alkanolamines, aldehydes in the presence of K CO yield di-tertiary amines, which, on distillation, break down into a,P unsaturated amines and secondary amines. With a mono- or dialkanolamine, an alkaU metal cyanide, and an aldehyde or ketone, aminoacetonitriles are formed. 

Method 3. Reductive alkylation reaction of an amine or ammonia and hydrogen with an aldehyde or ketone over a hydrogenation catalyst. 

Reductive amination ol aldehydes or ketones by cyanoborohydride (or tnacetoxyborohydride) anion Selective reduction of carbonyls to alcohol, oximes to N alkylhydroxylarmnes, enamines to amines... 

In Robinson s now well-known suggestions, regarding the processes by which alkaloids may be produced in plants, two main reactions are used j the aldol condensation and the similar condensation of carbinol-amines, resulting from the combination of an aldehyde or ketone with ammonia or an amine, and containing the group. C(OH). N., with substances in which the group, CH. CO. is present. By these reactions it is possible to form the alkaloid skeleton, and the further necessary changes postulated include oxidations or reductions and elimination of water for the formation of an aromatic nucleus or of an ethylene derivative. 

Many biological processes involve an "association" between two species in a step prior to some subsequent transformation. This association can take many forms. It can be a weak association of the attractive van der Waals type, or a stronger interaction such as a hydrogen bond. It can be an electrostatic attraction between a positively charged atom of one molecule and a negatively charged atom of another. Covalent bond formation between two species of complementary chemical reactivity represents an extreme kind of association. It often occurs in biological processes in which aldehydes or ketones react with amines via imine intermediates. 

The secondary amines used in the preparation of enamines have been primarily simple dialkylamines or cyclic amines of five- or higher-membered rings. Azetidine (4) yields a stable enamine with cyclopentanone (28). No simple enamines formed by condensation of ethylenimine (5) or a substituted ethylenimine with an aldehyde or ketone have been reported. 

Ternary iminium complex salts can be prepared by direct combination of an aldehyde or ketone with a secondary amine complex salt (95). An adaptation of this procedure employing the perchlorate salts of secondary amines provides a simple method for the preparation of the readily crystallized and nonhydroscopic ternary iminium perchlorates (96), Eq. (10). 

They found that a stoichiometric mixture of titanium tetrachloride, secondary amine, and aldehyde or ketone produeed enamines directly and rapidly [Eq. (11)]. 

For purposes of characterization of enamines the perchlorate salts are preferred, as they crystallize well, and the perchlorate anion has no tendency to add to the iminium cation. Other salts, including hexachlorostannates (13), hexachloroantimonates (13), chlorides, bromides, tetraphenylborates, and nitrates, have also been used. Recently a method for the preparation of iminium salts directly from aldehydes or ketones and the amine perchlorate has been reported (16). 

While the usual eonsequence of hydration of enamines is eleavage to a secondary amine and an aldehyde or ketone, numerous cases of stable carbinolamines are known (102), particularly in examples derived from cyclic enamines. The selective terminal hydration (505) of a cross-conjugated dienamine-vinylogous amide is an interesting example which gives an indication of the increased stabilization of the vinylogous amide as compared to simple enamines, which is also seen in the decreased nucleophilicity of the conjugated amino olefin-carbonyl system. 

An alkene activated by an electron-withdrawing group—often an acrylic ester 2 is used—can react with an aldehyde or ketone 1 in the presence of catalytic amounts of a tertiary amine, to yield an a-hydroxyalkylated product. This reaction, known as the Baylis-Hillman reaction, leads to the formation of useful multifunctional products, e.g. o -methylene-/3-hydroxy carbonyl compounds 3 with a chiral carbon center and various options for consecutive reactions. 

The reaction starts with the nucleophilic addition of a tertiary amine 4 to the alkene 2 bearing an electron-withdrawing group. The zwitterionic intermediate 5 thus formed, has an activated carbon center a to the carbonyl group, as represented by the resonance structure 5a. The activated a-carbon acts as a nucleophilic center in a reaction with the electrophilic carbonyl carbon of the aldehyde or ketone 1 ... 

Instead of formaldehyde, other aldehydes or ketones may be used—aliphatic as well as aromatic recently methylene dihalides have been employed with success. The amine component is often employed as hydrochloride in addition to... 

The reaction of carboxylic acids, aldehydes or ketones with hydrazoic acid in the presence of a strong acid is known as the Schmidt reaction A common application is the conversion of a carboxylic acid 1 into an amine 2 with concomitant chain degradation by one carbon atom. The reaction of hydrazoic acid with a ketone 3 does not lead to chain degradation, but rather to formation of an amide 4 by formal insertion of an NH-group. 

An enamine is easily prepared by reaction of the corresponding aldehyde or ketone 4 and a secondary amine 5. A cyclic secondary amine like pyrrolidine, piperidine or morpholine is most often used. A general procedure has been reported by Mannich and Davidseti in 1936 ... 

Mechanism of imine formation by reaction of an aldehyde or ketone with a primary amine. 

Reaction of an aldehyde or ketone with a secondary amine, R2NH, rather than a primary amine yields an enamine. The process is identical to imine formation up to the iminium ion stage, but at this point there is no proton on nitrogen that can be lost to form a neutral imine product. Instead, a proton is lost from the neighboring carbon (the a carbon), yielding an enamine (Figure 19.10). 

Mechanism of enamine formation by reaction of an aldehyde or ketone with a secondary amine, R2NH. The iminium ion intermediate has no hydrogen attached to N and so must lose H+ from the carbon two atoms away. 

An aldehyde or ketone reacts with a primary amine, RNH.2, to yield an imine, in which the carbonyl oxygen atom has been replaced by the =N-R group of the amine. Reaction of the same aldehyde or ketone with a secondary amine, R2NH, yields an enamine, in which the oxygen atom has been replaced by the -NR2 group of the amine and the double bond has moved to a position between the former carbonyl carbon and the neighboring carbon. 

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