Ketones enamine formation

A potentially more simple procedure is the Reformatsky condensation of the bromoester (47) with ketones a-methylenebutyrolactones are produced, in one step, in fair to good yield. An efficient three-step synthesis consisting of ketone enamine formation, Michael addition to ethyl / -nitro-acrylate, and borohydride reduction has been reported the last process affords a mixture of the cw-butyrolactone and the /ra j-hydroxyester as shown in Scheme 14. 

The presence of 1,3-diaxial interaction between the C-2 alkyl group and the C-4 axial hydrogen atom is reflected in the rate of enamine formation of 2-substituted cyclohexanone. It has been shown by Hunig and Salzwedel (20) that even under forcing conditions, the yield of pyrrolidine and morpholine enamines of 2-methylcyclohexanone does not exceed 58%, whereas the C-2 unsubstituted ketones underwent enamine formation under rather milder conditions in better than 80 % yield. 

C. Secondary Reactions in Enamine Formation from Ketones and Amines. ... 

This innovation was exploited by Stork and his co-workers (6-8) for a study of enamine formation from a variety of ketones and secondary amines. 

While enamines can usually be obtained directly from ketones and secondary amines their formation by an indirect route may bo advantageous. The previously mentioned condensation of rnethyl ketones during azeotropic enamine formation has prompted the alklyation (J) or acylation and reduction (59) of Schiff s bases. A parallel method uses the formation and desulfurization of N-acylthiazolines followed by hydride reduetion (60,61). 

The long known catalyses of some ketone condensation reactions by secondary amines, can be postulated to have their basis in the reactions of enamine intermediates with ketones. The unsuitability of methyl ketones for azeotropic enamine formation is based on this phenomenon. Recent studies in cyclization reactions have added further support to this concept (354). 

We have previously discussed that keto-aldehydes react with anilines first at the aldehyde carbon to form the aldimine. Subsequent condensation with another aniline formed a bis-imine or enamino-imine. The aniline of the ketimine normally cyclizes on the aldimine (24 —> 26). Conversely, cyclization of the aldimine could be forced with minimal aniline migration to the ketimine using PPA (30 —> 31). The use of unsymmetrical ketones has not been thoroughly explored a few examples are cited below. One-pot enamine formation and cyclization occurred when aniline 48 was reacted with dione 49 in the presence of catalytic p-TsOH and heat. Imine formation occurred at the less-hindered ketone, and cyclization with attack on the reactive carbonyl was preferred. ... 

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. 

Enamines behave in much the same way as enolate ions and enter into many of the same kinds of reactions. In the Stork reaction, for example, an enamine adds to an aqQ-unsaturated carbonyl acceptor in a Michael-like process. The initial product is then hydrolyzed by aqueous acid (Section 19.8) to yield a 1,5-dicarbonyi compound. The overall reaction is thus a three-step sequence of (11 enamine formation from a ketone, (2) Michael addition to an a,j3-unsaturated carbonyl compound, and (3) enamine hydrolysis back to a ketone. 

There is a distinct relationship between keto-enol tautomerism and the iminium-enamine interconversion it can be seen from the above scheme that enamines are actually nitrogen analogues of enols. Their chemical properties reflect this relationship. It also leads us to another reason why enamine formation is a property of secondary amines, whereas primary amines give imines with aldehydes and ketones (see Section 7.7.1). Enamines from primary amines would undergo rapid conversion into the more stable imine tautomers (compare enol and keto tautomers) this isomerization cannot occur with enamines from secondary amines, and such enamines are, therefore, stable. 

The reaction is exactly analogous to the chemical aldol reaction (also shown), but it utilizes an enamine as the nucleophile, and it can thus be achieved under typical enzymic conditions, i.e. around neutrality and at room temperature. There is one subtle difference though, in that the enzyme produces an enamine from a primary amine. We have indicated that enamine formation is a property of secondary amines, whereas primary amines react with aldehydes and ketones to form imines (see Section 7.7.1). Thus, a further property of the enzyme is to help stabilize the enamine tautomer relative to the imine. 

This catalytic enamine formation is limited to aldehydes and ketones as starting materials - it does not appear to be possible to prepare corresponding enamines , i.e. A,0-ketene acetals, from esters in this fashion. Nevertheless, the preparation of simple, reactive nucleophiles from normally electrophilic species, aldehydes and ketones, in a catalytic fashion sounds highly attfactive. Furthermore, the catalytic nature of these reactions allows the use of chiral amines, and the further possibility that these reactions can be rendered enantioselective. Enamines react readily with a wide variety of electrophiles, and the range of reactions that can be catalyzed by enamine catalysis is summarized in Scheme 2. 

The mechanism for the release of the substituted ketone is essentially the reverse of enamine formation. 

Stork Enamine Reaction Aldehydes and ketones react with secondary amines to form compounds called enamines. The general reaction for enamine formation can be written as... 

Secondary amine reacts with aldehyde and ketone to produce enamine. An enamine is an a,P-unsaturated tertiary amine. Enamine formation is a reversihle reaction, and the mechanism is exactly the same as the mechanism for imine formation, except the last step of the reaction. 

For the general condensation reaction of secondary amines with ketones to yield enamines, pyrrolidine, piperidine, or morpholine is generally used. The rate of enamine formation depends on the basicity of the secondary amine and the steric environment of the carbonyl group [12a, b, 29], Pyrrolidine, which is more basic, usually reacts faster than morpholine. The investigation of piperazine, a disecondary amine, has only been reported recently by Benzing [45, 46] and Sandler [41]. Surprisingly, the reaction of excess -butyraldehyde with piperazine in tetrahydrofuran at — 20°C to 0°C gave mainly AM-butenyl-piperazine [41] (see Eq. 13). 

An important pyrrole synthesis, known as the Knorr synthesis, is of the cyclizative condensation type. An a -amino ketone furnishes a nucleophilic nitrogen and an electrophilic carbonyl, while the second component, a /3-keto ester or similar /3-dicarbonyl compound, furnishes an electrophilic carbonyl and a nucleophilic carbon. The initial combination involves enamine formation between the primary amine and the dicarbonyl compound. Subsequent cyclization occurs as a result of the nucleophilic jg-carbon of the enamine adding to the electrophilic carbonyl group of the a-amino ketone (equation 76). Since a-amino... 

Enamine formation occurs by the thermolysis of diazo compounds (Scheme 150)67 109,278 284 288,304 332 453 454 via a carbene-like intermediate.284 332 When R1 = Ph, it enters into competition with hydrogen migration,284,332 and the electrophilic character of the carbene enhances the migration of the dimethylaminophenyl more than the phenyl.332 When triazoline synthesis is carried out at temperatures higher than that at which thermolysis of diazo compounds occurs, enamines are obtained exclusively, as in the addition of phenyl azide to cinnamic nitriles and ketones, with phenyl migration dominating in the nitrile.284 Enamine is also formed quantitatively in the reaction of ethyl diazoacetate with benzylideneaniline at 110°C.455... 

As with imines, enamine formation may be achieved using azeotropic distillation,219 or with the aid of molecular sieves. The procedure described in Expt 5.201 for the preparation of the enamine from morpholine and diisobutyl ketone utilises titanium(iv) chloride as a catalyst and water scavenger.220... 

Whereas the examples discussed so far proceed according to the iminium ion mechanism (A), amine-catalyzed additions of, e.g., ketones to nitroolefins are effected by intermediate enamine formation (B). List et al. were the first to report that L-proline catalyzes the addition of several ketones to nitroolefins (Scheme 4.23). Whereas both the yields and diastereoselectivity were high in DMSO as solvent, the ee did not exceed 23% [38]. A related study of this process by Enders and Seki resulted in identification of methanol as a superior solvent, and enantioselec-tivity up to 76% was achieved (Scheme 4.23) [39]. 

C-Nucleophiles have recently been added asymmetrically to azodicarboxylates as Michael-acceptors, resulting in a-amination of the nucleophilic component. Examples of this type of reaction, which is based on activation of the aldehyde or ketone component by enamine formation, are summarized in Scheme 4.27. Please note that this type of reaction is covered in more detail in chapter 7 of this book. 

Small chiral organic molecules may catalyze the asymmetric addition of ketones, and aldehydes to electron-deficient olefins, such as vinylidene acetones, nitroole-fins, enones, and vinyl sulfones. In this chapter we will describe the inter- and intramolecular reactions in which activation of the carbonyl compound takes place via enamine formation. 

Bronsted acid (Scheme 2.42) [26-28]. (For experimental details see Chapter 14.9.4). These catalysts mediate the addition of ketones to nitroalkenes at room temperature in the presence of a weak acid co-catalyst, such as benzoic acid or n-butyric acid or acetic acid. The acid additive allows double alkylation to be avoided, and also increases the reaction kinetic. The Jacobsen catalyst 24 showed better enantio- and diastereoselectivity with higher n-alkyl-ethyl ketones or with branched substrates (66 = 86-99% dr = 6/1 to 15/1), and forms preferentially the anti isomer (Scheme 2.42). The selectivity is the consequence of the preferred Z-enamine formation in the transition state the catalyst also activates the acceptor, and orientates in the space. The regioselectively of the alkylation of non-symmetric ketones is the consequence of this orientation. Whilst with small substrates the regioselectivity of the alkylation follows similar patterns (as described in the preceding section), leading to products of thermodynamic control, this selectivity can also be biased by steric factors. 

The reaction of an aldehyde or a ketone with a secondary amine follows exactly the same mechanism as the reaction with a primary amine (see Figure 18.3) until the final step. Unlike the case with a primary amine, the nitrogen of the iminium ion does not have a proton that can be removed to produce a stable imine. Therefore, a proton is removed from an adjacent carbon, resulting in the formation of an enamine. Enamine formation is illustrated in the following equations. In each case the equilibrium is driven toward the products by removal of water. 

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