Primary enamines hydrolysis

Vinyl azides react with alkyl-lithium reagents to form a-substituted ketones, after hydrolysis of the intermediate primary enamine [equation (9)]. The vinyl... 

This new impurity proved to be derived from the Pd-catalyzed oxidation of DIPA to the enamine via P-hydride elimination. In fact, mixing Pd(OAc)2 with DIPA in DMF-d7 readily formed Pd black along with two species, primary amine and acetone, presumably derived from the enamine through hydrolysis. The resulting enamine or acetone then underwent a coupling reaction with iodoaniline 28. Heterocyclization through the arylpalladium(II) species provided 2-methyl indole 71, as shown in Scheme 4.19. 

In the reduction of imines and enamines with hydrogen telluride and sodium hydrogen telluride, hydrolysis leading to primary amines and carbonyl compounds is frequently competitive with the reduction. This undesired side reaction is minimized by the addition of triethylamine, in the case of hydrogen telluride. ... 

In related asymmetric Michael-additions of enamine (206) and 2-aryl- 1-nitro-ethylenes, only one of the four possible enantiomerically pure diastereomers was formed 204). Hydrolysis of the crude primary products furnished a-alkylated cyclohexanones of > 90 % enantiomeric excess 204). 

Copper(I) salts of enamines have been allylated with the 2-allyloxybenzimidazoles to give y,5-unsaturated ketones upon hydrolysis (79CL957). Primary allylic ethers react preferentially at their a-carbon with retention of double bond configuration whereas secondary allylic ethers react mainly at the y-carbon to afford alkenes of predominantly (E)-stereochemistry. 

Asymmetric Michael addition to to-nitrostyrenes,2 The enamine (2) formed from cyclohexanone and this prolinol derivative reacts with 2-aryl-1-nitroethylenes (3) to form, after acid hydrolysis of the primary adduct, essentially only one (4) of the four possible y-nitro ketones. 

It is possible that conjugated enamines such as enaminones hydrolyze by the mechanism shown in Scheme 2, a variation of Scheme 1 in which nucleophilic hydration occurs on an O-protonated enamine rather than on the C-protonated (iminium) ion. This mechanism has been proposed for the acidic hydrolysis of compounds 36 and 37. This mechanism cannot be considered established, however, as the experiments that would rule out C-protonation were not done. It is highly pertinent that hydrolyses of other conjugated enamines, 10,11, 25, 26,39 and 40, all obey the expectations of Scheme 1, equation 15, namely they exhibit general-acid catalysis and (for 25, 26, 39 and 40) primary kinetic solvent isotope effects. 

List " suggested that the proline-catalyzed Mannich reaction proceeds in close analogy to the proline-catalyzed aldol reaction. As detailed in Scheme 6.10, the ketone and proline combine to form an enamine. The aldehyde reacts with a primary amine (usually an aniline derivative) giving an imine. The enamine and imine then combine to produce, after hydrolysis, the Mannich product. 

The corresponding reactions of enamine with dialkyl diazenedicarboxylates19 and asymmetric diazenes20-23 are more complex and can lead initially to either the oxadiazines 21 (cis ring junction)21 or the substituted enamines 22 and 23. An equilibrium is then attained between the different products, depending on the structure (n.X) of the enamine and on the nature of the substituents (Y,Z) of the diazene. Further reaction of the primary products with a second diazene molecule can occur. The corresponding ketones arc then produced by acidic hydrolysis. 

The reductive coupling of carbonyl compounds with formation of C-C double bonds was developed in the early seventies and is now known as McMurry reaction [38, 39]. The active metal in these reactions is titanium in a low-valent oxidation state. The reactive Ti species is usually generated from Ti(IV) or Ti(III) substrates by reduction with Zn, a Zn-Cu couple, or lithium aluminum hydride. A broad variety of dicarbonyl compounds can be cyclized by means of this reaction, unfunctionalized cycloalkenes can be synthesized from diketones, enolethers from ketone-ester substrates, enamines from ketone-amide substrates [40-42], Cycloalkanones can be synthesized from external keto esters (X = OR ) by subsequent hydrolysis of the primary formed enol ethers (Scheme 9). 

Alkylation with simple alkyl halides is generally a poor reaction with enamines. Alkylation often takes place on nitrogen instead of carbon, and Stork and others7 have developed the aza-enolates to remedy this deficiency. A primary amine, usually cyclohexylamine, combines with an aldehyde to form an imine 42. Treatment with LDA 43 gives the lithium derivative, the analogue of a lithium enolate, known as an azaenolate 44. These intermediates are alkylated reliably at carbon 45 with most primary, and even with secondary alkyl halides, to give the alkylated aldehyde 47 after hydrolysis of the imine 46. 

In aqueous acidic solutions, an enamine is hydrolyzed back to the carbonyl compound and secondary amine, a reaction that is similar to the acid-catalyzed hydrolysis of an imine back to the carbonyl compound and a primary amine. 

The 4-(chloromethyl)isoxazole 13, which is readily accessible from 3,5-dimethyloxazole, serves as a C4-building-block in annulations to cycloalkanones (isoxazole annelation according to Stork). The primary step is alkylation leading to product 14, a masked triketone. On hydrogenation, the isoxazole ring is reductively opened and cyclization via the enaminone 15 leads to the enamine 16. On treatment with sodium hydroxide, this is converted into the bicycloenone 17 by hydrolysis, acid fission of the y dicarbonyl system and an intramolecular aldol condensation (analogous to a Robinson annu-lation) ... 

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