Enamines examples

The dual nature of enamine-iminium pairs allows unique possibilities for domino processes. Reactions of enamines with electrophiles afford electrophilic iminium ions that are ready to react with another (internal or external) nucleophile. Conversely, reactions of unsaturated imininm ions with nucleophiles afford enamines. Examples of intramolecular enamtne-catalyzed domino processes are depicted in Scheme 35. In all of these reactions, both enamine and iminium mediated steps can be distinguished. 

Table I2B.I Transformed response values from the enamine example...

Another similar example concerns the alkylation of enamines. This reaction works well with reactive a-halocarbonyl compounds (frames 175ff) but simple alkyl hahdes often react on nitrogen ... 

Difunctional target molecules are generally easily disconnected in a re/ro-Michael type transform. As an example we have chosen a simple symmetrical molecule, namely 4-(4-methoxyphenyl)-2,6-heptanedione. Only p-anisaldehyde and two acetone equivalents are needed as starting materials. The antithesis scheme given helow is self-explanatory. The aldol condensation product must be synthesized first and then be reacted under controlled conditions with a second enolate (e.g. a silyl enolate plus TiCl4 or a lithium enolate), enamine (M. Pfau, 1979), or best with acetoacetic ester anion as acetone equivalents. 

One route to o-nitrobenzyl ketones is by acylation of carbon nucleophiles by o-nitrophenylacetyl chloride. This reaction has been applied to such nucleophiles as diethyl malonatc[l], methyl acetoacetate[2], Meldrum s acid[3] and enamines[4]. The procedure given below for ethyl indole-2-acetate is a good example of this methodology. Acylation of u-nitrobenzyl anions, as illustrated by the reaction with diethyl oxalate in the classic Reissert procedure for preparing indolc-2-carboxylate esters[5], is another route to o-nitrobenzyl ketones. The o-nitrophenyl enamines generated in the first step of the Leimgruber-Batcho synthesis (see Section 2.1) are also potential substrates for C-acylation[6,7], Deformylation and reduction leads to 2-sub-stituted indoles. 

This genera] scheme could be used to explain hydrogen exchange in the 5-position, providing a new alternative for the reaction (466). This leads us also to ask whether some reactions described as typically electrophilic cannot also be rationalized by a preliminary hydration of the C2=N bond. The nitration reaction of 2-dialkylaminothiazoles could occur, for example, on the enamine-like intermediate (229) (Scheme 141). This scheme would explain why alkyl groups on the exocyclic nitrogen may drastically change the reaction pathway (see Section rV.l.A). Kinetic studies and careful analysis of by-products would enable a check of this hypothesis. 

Oxidative dimerization of various 2-benzyloxy-2-thiazoline-5-ones (222) catalyzed by iodine and triethylamine is another example of the nucleophilic reactivity of the C-4 atom (469) (Scheme 112). Treatment of 212 with pyrrolidinocyclohexene yields the amide (223) (Scheme 113). The mechanism given for the formation of 223 is proposed by analogy with the reactivitx of oxazolones with enamines (4701. 4-Substituted 2-phenylthiazol-5(4Hi-ones react with A -morphoiino-l-cyclohexene in a similar manner (562j. Recently. Barret and Walker have studied the Michael addition products... 

Carbinolamines are formed by nucleophilic addition of an amine to a carbonyl group and are intermediates in the for mation of imines and enamines Carbocation (Section 4 8) Positive ion in which the charge re sides on carbon An example is tert butyl cation (CH3)3C Carbocations are unstable species that though they cannot normally be isolated are believed to be intermediates in certain reactions... 

Reaction conditions depend on the reactants and usually involve acid or base catalysis. Examples of X include sulfate, acid sulfate, alkane- or arenesulfonate, chloride, bromide, hydroxyl, alkoxide, perchlorate, etc. RX can also be an alkyl orthoformate or alkyl carboxylate. The reaction of cycHc alkylating agents, eg, epoxides and a2iridines, with sodium or potassium salts of alkyl hydroperoxides also promotes formation of dialkyl peroxides (44,66). Olefinic alkylating agents include acycHc and cycHc olefinic hydrocarbons, vinyl and isopropenyl ethers, enamines, A[-vinylamides, vinyl sulfonates, divinyl sulfone, and a, P-unsaturated compounds, eg, methyl acrylate, mesityl oxide, acrylamide, and acrylonitrile (44,66). 

These compounds typically react with electrophiles on carbon and in this respect they resemble enamines, enol ethers and enol thioethers. For example, both pyrrole and 1-pyrrolidinocyclohexene can be C-acetylated (Scheme 4). 

A/ -Methoxycarbonyl-2-pyrroline undergoes Vilsmeier formylation and Friedel-Crafts acylation in the 3-position (82TL1201). In an attempt to prepare a chloropyrroline by chlorination of 2-pyrrolidone, the product (234) was obtained in 62% yield (8UOC4076). At pH 7, two molecules of 2,3-dihydropyrrole add together to give (235), thus exemplifying the dual characteristics of 2,3-dihydropyrroles as imines and enamines. The ability of pyrrolines to react with nucleophiles is central to their biosynthetic role. For example, addition of acetoacetic acid (possibly as its coenzyme A ester) to pyrroline is a key step in the biosynthesis of the alkaloid hygrine (236). 

The synthetic application of reactions based upon the intramolecular addition of a carbanion or its enamine equivalent to a carbonyl or nitrile group has been explored extensively. One class of such reactions, namely the Dieckman, has already been discussed in Section 3.03.2.2, since ring closure can often occur so as to form either the C(2)—C(3) or C(3)—C(4) bond of the heterocyclic ring. Some illustrative examples of the application of this type of ring closure are presented in Scheme 46. 

An example of non-aromatic tautomerism has already been quoted (Table 13, Section 4.04.1.3.3(ii)) the equilibrium between the two enamines (152a) and (152b) is solvent and temperature dependent (70BSF3147). 

Formal addition products of 1,3-dipoles are compiled in a recent review (79AHC(24)63). Examples include addition to a nitrone forming a six-membered ring, to an enamine forming a pyrazolidine ring, and to the C=0 bond of diphenylcyclopropenone. 

There are also substituents that can act as electron-releasing groups through resonance. Among familiar examples are alkoxy and amino groups in vinyl ethers and enamines, respectively. 

The chemical reactivity of these two substituted ethylenes is in agreement with the ideas encompassed by both the MO and resonance descriptions. Enamines, as amino-substituted alkenes are called, are vety reactive toward electrophilic species, and it is the p carbon that is the site of attack. For example, enamines are protonated on the carbon. Acrolein is an electrophilic alkene, as predicted, and the nucleophile attacks the P carbon. 

Secondary amines cannot form imines, and dehydration proceeds to give carbon-carbon double bonds bearing amino substituents (enamines). Enamines were mentioned in Chapter 7 as examples of nucleophilic carbon species, and their synthetic utility is discussed in Chapter 1 of Part B. The equilibrium for the reaction between secondary amines and carbonyl compounds ordinarily lies far to the left in aqueous solution, but the reaction can be driven forward by dehydration methods. 

Androst-4-ene-3,l 1,17-trionehas been converted into several 3,17-dienamine derivatives which, on reduction with LiAlH4 followed by removal of the protecting groups, give 11 jS-hydroxyandrost-4-ene-3,17-dione. An unsaturated 3-ketone has also been protected as an enamine in the LiAlH4 reduction of a 21-ester group a further example is the conversion of 7-methylene-5a-an-drostane-3,17-dione into the 3-pyrrolidine enamine followed by reduction of the 17-ketone by Li[OC(CH3)3]3 AlH. ... 

Extensions of this concept have utilized enamine hydrolysis (171, X = R N) and the quenching of the enolate anion (171, X = O ) e.g. ref. 353). a,(i-Un-saturated ketones are usually more stable than their p,y counterparts, but there are notable exceptions to this, and in such cases the deconjugated ketone may be isolated from the equilibrated system. For example, retro steroids (9, 10a) have a large proportion of A -3-ketone at equilibrium, and 17-ketones yield the more stable A -system on treatment with acid. ... 

In their original communication on the alkylation and acylation of enamines, Stork et al. (3) had reported that the pyrrolidine enamine of cyclohexanone underwent monoacylation with acid chlorides. For example, the acylation with benzoyl chloride led to monobenzoylcyclohexanone. However, Hunig and Lendle (33) found that treatment of the morpholine enamine of cyclopentanone with 2 moles of propionyl chloride followed by acid hydrolysis gave the enol ester (56), which was proposed to have arisen from the intermediate (55). 

Mimk and Kim (60) have reported the preparation of the enamines of several acyclic ketones by refluxing the ketone with the amine for 66 hr to 76 days. For example the morpholine enamine of 2-pentanone was found to consist only of 121. 

Another interesting example is found in the morpholine enamine of 2- -propylcyclohexanone (138), which consists of a 2 3 mixture of tri- and tetrasubstituted isomers. The radical ion from the tetrasubstituted isomer loses an ethyl radical, giving the base peak at m/e 180. 

The primary objectives of this chapter are to detail the methods by which enamines (a,/3-unsaturated amines) (I) can be synthesized and the mechanisms of enamine formation. The enamines discussed are those in which the nitrogen is tertiary and, with the exception of a few selected examples, Contain no other functional groups. The term simple enamines might be used to describe the majority of enamines noted in this chapter. 

Most of the following methods represent less general preparative routes to enamines. In some examples the enamines produced can be obtained via methods already described in preceding sections, while in other examples the enamines produced are uniquely synthesized. In an attempt to present these miscellaneous preparations in other than a random order, they have been divided into reactions involving alkylations (A) and others (B). 

An example of the use of NMR spectroscopy to ascertain with reasonable certainty the stereochemistry of a series of enamines has been provided by Paquette (25). Based on a study of the NMR spectra of the endo- and exo-5-norbornene-2-carboxaldehydes (168), the enamine mixtures were estimated to contain 80 to 90 % of the transoid form (170). 

It has been shown (140) that enamines react as well, if not better, under the conditions of the Leuckart-Wallach reaction to give amines than do ketones in the presence of ammonia, primary amines, or secondary amines. This implies that in the Leuckart-Wallach reaction the pathway may be through the enamine and, of course, the iminium salt. The Leuckart-Wallach reaction has been reviewed (141). Examples of enamines reduced under the conditions of the Leuckart-Wallach reaction are listed in Table 12. 

The reaction of enamines with ketene (146) and sulfene (147) are presumed to proceed by a two-step process involving an iminium intermediate such as 99. In fact, reaction with all electrophilic olefins such as acrylonitrile and related reagents could be thought of as going through an iminium intermediate similar to 99. Another example is given by addition to an enamine... 

Heterocyclic enamines often undergo two-step 1,3 cycloaddition with methyl vinyl ketone. This involves electrophilic attacks by an olefinic carbon and by a carbonyl carbon (24,25). For example, 1,2-dimethyl-Zl -pyrroline (14), when treated with methyl vinyl ketone, produces 1,6-dimethyl-2,3,4,5-tetrahydroindole (15) (24). The requirement which must be met so that this type of cyclization reaction can take place is that the a position of the heterocyclic enamine be carbon substituted. This provides... 

The initial reaction between a ketene and an enamine is apparently a 1,2 cycloaddition to form an aminocyclobutanone adduct (58) (68-76a). This reaction probably occurs by way of an ionic zwitterion intermediate (75). The thermal stability of this adduct depends upon the nature of substituents Rj, R2, R3, and R. The enolic forms of 58 can exist only if Rj and/or R4 are hydrogens. If the enamine involved in the reaction is an aldehydic enamine with no 3 hydrogens and the ketene involved is di-substituted (i.e., R, R2, R3, and R4 are not hydrogens), then the cyclo-butanone adduct is thermally stable. For example, the reaction of dimethyl-ketene (61) with N,N-dimethylaminoisobutene (10) in isopropyl acetate... 

Diphenylcyclopropenone (76) undergoes a true 1,2 cycloaddition with alicyclic enamines followed by the breaking of sigma bonds in the intermediate (35,56). For example, when diphenylcyclopropenone (76) is... 

Bifunctional molecules undergo intermolecular cyclizations with enamines through simple alkylations 112-114) and acylations 115). For example, the reaction between l-(N-pyrrolidino)cyclopentene and 1,4-diiodobutane produces, after hydrolysis, ketospirans 92 and 93 113). 

Many acyclic enamines form thioamides when they are allowed to react with elemental sulfur at room temperature in dimethylformamide solvent 138). They also produce cyclic 1,3-dithiole by-products, which become main products at higher temperatures 135). For example, the reaction of l-(N-morpholino)-l-phenylethene (106) and sulfur in dimethylformamide solvent yields 1,3-dithiole 107. 

Dienamines undergo 1,4 cycloaddition with sulfenes as well as 1,2 cycloaddition. For example, l-(N,N-diethylamino)butadiene (111), when treated with sulfene (generated from methanesulfonyl chloride and triethyl-amine), produces 1,4 cycloadduct 116 in an 18 % yield and di-1,2-cycloadduct 117 in a 60 % yield (160). Cycloadduct 116 was shown not to be the precursor for 117 by treating 116 with excess sulfene and recovering the starting material unchanged (160). This reaction probably takes place by way of zwitterion 115, which can close in either a 1,4 or 3,4 manner to form cycloadducts 116 and 118, respectively. The 3,4 cycloaddition would then be followed by a 1,2 cycloaddition of a second mole of sulfene to form 117. Cycloadduct 117 must form in the 3,4 cycloaddition followed by a 1,2-cycloaddition sequence rather than the reverse sequence since sulfenes undergo cycloaddition only in the presence of an electron-rich olefinic center (159). Such a center is present as an enamine in 118, but it is not present in 119. 

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