Ketones enamine addition

Fluorme-containing Michael addition acceptors have been used as synthons, a portion of a molecule recognizably related to a simpler molecule, for the introduction of fluorine into the organic molecules Their reactions with enamines and ketones lead to a condensarion-cyclization process... 

A unique method to generate the pyridine ring employed a transition metal-mediated 6-endo-dig cyclization of A-propargylamine derivative 120. The reaction proceeds in 5-12 h with yields of 22-74%. Gold (HI) salts are required to catalyze the reaction, but copper salts are sufficient with reactive ketones. A proposed reaction mechanism involves activation of the alkyne by transition metal complexation. This lowers the activation energy for the enamine addition to the alkyne that generates 121. The transition metal also behaves as a Lewis acid and facilitates formation of 120 from 118 and 119. Subsequent aromatization of 121 affords pyridine 122. 

Alkylation of enamines Addition of amines to triple-bond compounds Addition of amines to aldehydes or ketones Reaction between Grignard reagents and formamides Reaction of phosphonates with aldehydes or ketones... 

Formation of enamines (addition of amines to aldehydes or ketones)... 

The first examples of a Michael-Stork enamine addition to allenyl esters and ketones R1CH=C=C(R2)COX (X = alkyl, alkoxyl) has been reported. Mechanistic investigation revealed that 2 equiv. of enamine are required for optimum yields. In the case of an allenyl methyl ketone, cyclopentyl enamine addition afforded 8-oxobicyclo[3.2.1]octane, providing evidence for the in situ formation of an enamine intermediate following the initial Michael-Stork reaction.187... 

Michael addition of metal enolates to a,/3-unsaturated carbonyls has been intensively studied in recent years and provides an established method in organic synthesis for the preparation of a wide range of 1,5-dicarbonyl compounds (128) under neutral and mild conditions . Metal enolates derived from ketones or esters typically act as Michael donors, and a,-unsaturated carbonyls including enoates, enones and unsaturated amides are used as Michael acceptors. However, reaction between a ketone enolate (125) and an a,/3-unsaturated ester (126) to form an ester enolate (127, equation 37) is not the thermodynamically preferred one, because ester enolates are generally more labile than ketone enolates. Thus, this transformation does not proceed well under thermal or catalytic conditions more than equimolar amounts of additives (mainly Lewis acids, such as TiCU) are generally required to enable satisfactory conversion, as shown in Table 8. Various groups have developed synthons as unsaturated ester equivalents (ortho esters , thioesters ) and /3-lithiated enamines as ketone enolate equivalents to afford a conjugate addition with acceptable yields. 

One of the most studied processes is the direct intermolecular asymmetric aldol condensation catalysed by proline and primary amines, which generally uses DMSO as solvent. The same reaction has been demonstrated to also occur using mechanochemical techniques, under solvent-free ball-milling conditions. This chemistry is generally referred to as enamine catalysis , since the electrophilic substitution reactions in the a-position of carbonyl compounds occur via enamine intermediates, as outlined in the catalytic cycle shown in Scheme 1.1. A ketone or an a-branched aldehyde, the donor carbonyl compound, is the enamine precursor and an aromatic aldehyde, the acceptor carbonyl compound, acts as the electrophile. Scheme 1.1 shows the TS for the ratedetermining enamine addition step, which is critical for the achievement of enantiocontrol, as calculated by Houk. ... 

The nucleophilic properties of enamines uncovered by Stork have found a wide application in Michael additions. Secondary enamines are usually in equilibrium with the corresponding imines. These imines are generally more stable, unless the tautomeric enamine is stabilized by conjugation (Figure 7.71). The primary product of the reaction of an enamine with an a,P-unsaturated carbonyl compound is a dipolar intermediate 7.108. This intermediate is converted to a 1,5-dicarbonyl compound on exposure to aqueous add. Proton transfers can take place before hydroysis to the ketone occurs, and the stereoselectivity of the process may be determined by such steps. Moreover, the enamine addition reaction can be reversible. These problems notwithstanding, the use of chiral amines to generate imines or enamines for use as Michael donors has been widely developed. The chiral imine/enamine can be preformed or, espedally in the case of intramolecular reactions, the amine can be added to the reaction medium in stoichiometric amounts. 

There are other methods for preparing enamines from ketones that utilize strong dehydrating reagents to drive the reaction to completion. For example, mixing carbonyl compounds and secondary amines followed by addition of titanium tetrachloride rapidly gives enamines. This method is applicable to hindered as well as to ordinary amines. Another procedure involves converting the secondary amine to... 

Without additional reagents Reactions with tris(dialkylamino)boranes Carboxylic acid amides from carboxylic acids Enamines from ketones... 

Finally a general approach to synthesize A -pyrrolines must be mentioned. This is tl acid-catalyzed (NH4CI or catalytic amounts of HBr) and thermally (150°C) induced tea rangement of cyclopropyl imines. These educts may be obtained from commercial cyan> acetate, cyclopropyl cyanide, or benzyl cyanide derivatives by the routes outlined below. Tl rearrangement is reminiscent of the rearrangement of 1-silyloxy-l-vinylcyclopropancs (p. 7 83) but since it is acid-catalyzed it occurs at much lower temperatures. A -Pyrrolines constitut reactive enamines and may be used in further addition reactions such as the Robinson anei lation with methyl vinyl ketone (R.V. Stevens, 1967, 1968, 1971). 

Primary amines undergo nucleo philic addition to the carbonyl group of aldehydes and ketones to form carbinol amines These carbinolamines dehydrate under the conditions of their formation to give N substituted imines Secondary amines yield enamines... 

A number of alternative multi-step procedures for the synthesis of a-tert-alkyl ketones are known, none of which possess wide generality. A previous synthesis of 2-tert-penty1cyclopentanone involved reaction of N-1-cyclopentenylpyrrol 1 dine with 3-chloro-3-methy1-l-butyne and reduction of the resulting acetylene (overall yield 46 ). However, all other enamines tested afford much lower yields. Cuprate addition to unsaturated ketones may be useful in certain cases. Other indirect methods have been briefly reviewed. ... 

The propensity for conjugate addition is diminished with A" -3-ketones due to steric hindrance. Thus A -3-alkyl ethers, as well as the corresponding thiobenzyl ethers and enamines, are formed selectively and in good yield from A" -3-ketones in the presence of 17- and 20-ketones. 

Steroidal A -dienamines are formed with a high degree of selectivity in the presence of 17- or 20-ketones. Preparation of morpholine and pyrrolidine enamines is achieved by azeotropic removal of water with or without a catalyst. Pyrrolidine enamines are also formed efficiently by addition of the base to the hot solution of the ketone in methanol followed by immediate cooling. ... 

Cross-conjugated dienones are quite inert to nucleophilic reactions at C-3, and the susceptibility of these systems to dienone-phenol rearrangement precludes the use of strong acid conditions. In spite of previous statements, A " -3-ketones do not form ketals, thioketals or enamines, and therefore no convenient protecting groups are available for this chromophore. Enol ethers are not formed by the orthoformate procedure, but preparation of A -trienol ethers from A -3-ketones has been claimed. Another route to A -trien-3-ol ethers involves conjugate addition of alcohol, enol etherification and then alcohol removal from la-alkoxy compounds. 

It is more reactive than perchloryl fluoride and therefore not without danger. It forms, for instance, a highly explosive product with pyridine. Like perchloryl fluoride it reacts with enol ethers, esters and enamines, but at lower temperature (—78°) to yield the fluorinated ketones as well as addition... 

At reflux, tetrahydrafuran slowly adds to terminal perfluoroalkylethylenes, perfluoroalkylacetylenes, and ethyl perfluoroalkylpropynoates [25] (equation 18) By contrast, the ionic addition of enamines to hexaJluoro-2-butyne is exothermic and gives dieneamines that, on acidic hydrolysis, yield fluoroalkenyl ketones [26] (equation 19)... 

Risaliti et al. (22), have shown that in the addition of the electrophilic olefins to the enamines of cyclohexanone, the formation of the less substituted enamine is favored when a bulky group is present at the electrophilic carbon atom. For instance, the reaction of (8-nitrostyrene with the morpholine enamine of cyclohexanone gave only the trisubstituted isomer (30) with the substituent in the axial orientation (23). The product on hydrolysis led to the ketone (31) to which erythro configuration was assigned on the grounds illustrated in Scheme 3 (24). 

The enamines derived from cyclic ketones give the normal alkylated products, although there is some evidence that unstable cycloadducts are initially formed (55b). Thus the enamine (28) derived from cyclohexanone and pyrrolidine on reaction with acrylonitrile, acrylate esters, or phenyl vinyl sulfone gave the 2-alkylated cyclohexanones (63) on hydrolysis of the intermediates (31,32,55,56). These additions are sensitive to the polarity of the solvent. Thus (28) in benzene or dioxane gave an 80% yield of the... 

The difunctionality of the enamines of cyclic ketones toward phenyl isocyanate provides the ideal situation for a potential polymer. The properties of the polyamides produced by addition of various diisocyanates to the enamines of cyclic ketones have been reported Ilia). 

The preparation of enamine ketones by addition of a,jS-unsaturated ketones to enamines is described in Chapter 4. 

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