Enamines, reactions acylation

In the acylation of enamines derived from 3-substituted cyclohexanones, 6-acylated products were favored over 2-acylated products (398), thus revealing another selective enamine reaction sequence. The use of oxalyl bromide for the acylation of enamines has also been described (399). 

Among other methods for the preparation of alkylated ketones are (1) the Stork enamine reaction (12-18), (2) the acetoacetic ester synthesis (10-104), (3) alkylation of p-keto sulfones or sulfoxides (10-104), (4) acylation of CH3SOCH2 followed by reductive cleavage (10-119), (5) treatment of a-halo ketones with lithium dialkyl-copper reagents (10-94), and (6) treatment of a-halo ketones with trialkylboranes (10-109). 

Pyridines and their N- oxides undergo attack by enamines under acylating conditions (Scheme 168), and the results for reactions of N- oxides have been surveyed (B-71MI20500). A modification of this heteroarylation reaction has been employed in the first step of a new synthesis of the antitumor alkaloid olivacine (241 Scheme 169) (81CC44). Electron-withdrawing groups attached at C-4 in the pyridine nucleus appear to facilitate this reaction. 

Enamines are intermediate in reactivity more reactive than an enol, but less reactive than an enolate ion. Enamine reactions occur under milder conditions than enolate reactions, so they avoid many side reactions. Enamines displace halides from reactive alkyl halides, giving alkylated iminium salts. The iminium ions are unreactive toward further alkylation or acylation. The following example shows benzyl bromide reacting with the pyrrolidine enamine of cyclohexanone. 

The enamine reaction provides an alternative method for selective alkylation and acylation of aldehydes and ketones. The enamine group is both a protecting group for carbonyl compounds and a directing or activating group for further elaboration. Note the relationship between enolates and enamines ... 

Stork enamine reaction. Synthesis of a-al-kyl or a-acyl carbonyl compounds from enamines and alkyl or acyl halides. 

Reaction of enamines with acyl halides followed by hydrolysis leads to ji-diketones. The apparent violation of the HSAB principle is due to the lack of a forward path for the A -acyl intermediates. C-Acylation is the only feasible reaction course. 

The use of enamines as synthetic intermediates for the alkylation and acylation at the a-carbon of aldehydes and ketones was pioneered by Gilbert Stork of Columbia University. This use of enamines is called the Stork enamine reaction. 

Enamines undergo acylation when treated with acid chlorides and acid anhydrides. The reaction is a nucleophilic acyl substitution as illustrated by the conversion of cyclohexanone, via its pyrrolidine enamine, to 2-acetylcyclohexanone. 

The nucieophiiicity of the carbon of enamines makes them particularly useful reagents in organic synthesis because they can be acylated, alkylated, and used in Michael additions (see Section 19.7A). Enamines can be used as synthetic equivalents of aldehyde or ketone enolates because the alkene carbon of an enamine reacts the same way as does the a carbon of an aldehyde or ketone enolate and, after hydrolysis, the products are the same. Development of these techniques originated with the work of Gilbert Stork of Columbia University, and in his honor they have come to be known as Stork enamine reactions. 

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. 

Tnalkylindoles undergoFnedel-Crafts reactions at position 6, however, in tnfluoroacetic anhydride the a-methyl group of 1,2,3-trimethylindole is acylated through an intermediate enamine [41, 42] (equation 27) Similarly, tnfluoroacetic anhydnde acylates the double bond of the a-methylene compound shown [42] (equation 28)... 

That the methyl group in the less substituted isomer of the enamine (20) is axial was borne out by the work of Johnson et al. (18) in the total synthesis of the glutarimide antibiotic //-dehydrocycloheximide (24). The acylation of the morpholine enamine of 2,4-dimethylcyclohexanone (25) with 3-glutarimidylacetylchloride (26), followed by the hydrolysis of the intermediate product (27) with an acid buffer, led to the desired product in 35 % yield. The formation of the product in a rather low yield could most probably be ascribed to the relatively low enamine-type aetivity exhibited by the tetrasubstituted isomer, which fails to undergo the acylation reaction, and also because in trisubstituted isomer one of the CHj groups is axial. Since the methyl groups in the product are trans to each other, the allylic methyl group in the less substituted isomer of the enamine should then be in the axial orientation. 

Lochte and Pitman (44) have reported the cyanoethylation of the pyrrolidine enamine of 3-methylcycIopentanone (84), the product being a mixture of C-2 and C-5 cyanoethylated ketones (85 and 86). Hunig and Salzwedel 20) have obtained a mixture of C2- and C5-acylated products from the reaction of morpholine enamine of 3-methylcyclopentanone with propionyl chloride. 

Experimental evidence, obtained in protonation (3,6), acylation (1,4), and alkylation (1,4,7-9) reactions, always indicates a concurrence between electrophilic attack on the nitrogen atom and the -carbon atom in the enamine. Concerning the nucleophilic reactivity of the j3-carbon atom in enamines, Opitz and Griesinger (10) observed, in a study of salt formation, the following series of reactivities of the amine and carbonyl components pyrrolidine and hexamethylene imine s> piperidine > morpholine > cthyl-butylamine cyclopentanone s> cycloheptanone cyclooctanone > cyclohexanone monosubstituted acetaldehyde > disubstituted acetaldehyde. 

The reaction of the enamine (96) with acetyl chloride was reported (72) to afford no acyl derivative but the aminocyclobutanone (97) and the hydrochloride of the enamine. 

Acylation of the enamine (113) with a,/9-unsaturated acid chlorides has been shown (57) to give bicyclo(3.3.1)nonan-2,9-diones. Acryloyl ehloride on reaction with the enamine (113) and subsequent hydrolysis gave bicyelo-(3.3.1)nonan-2,9-dione (123). Mechanistic studies suggest that C alkylation by the olefin precedes acylation (87). 

The reaction of ketene with the enamine (113) is reported (88) to give l-morpholino-2-acetyl-l-cyclohexene i.e., the enamino ketone expected from acylation of (113). The pyrrolidine enamine (28), however, has been shown to react (73) with excess ketene to give the a-pyrone (124). On the... 

The acylation of enamino ketones can take place on oxygen or on carbon. While reaction at nitrogen is a possibility, the N-acylated products are themselves acylating agents, and further reaction normally takes place. The first reported acylation of enamino ketones (72) was that of 129, prepared by acylation of the enamine (113), which was shown to have undergone O acylation because on mild hydrolysis the enol ester (130) could be isolated. A similar reaction took place with other aliphatic acid chlorides (80) and with dibasic acid chlorides [e.g., with succinyl chloride to give 118 above]. 

The aromatic sulfonyl chlorides which have no a-hydrogen and thus cannot form sulfenes give acylic sulfones. Thus 1-piperidinopropene on reaction with benzene sulfonyl chloride (9J) gave 2-benzenesulfonyl-l-piperidinopropene (153). Similarly the enamine (28) reacts with p-toluene-sulfonyl chloride to give the 2-p-toluenesulfonylcyclohexanone (154) on hydrolysis (/OS). 

The reaction of the enamines of cyclic ketones with alkyl isocyanates, acyl isocyanates, phenyl isothiocyanates, and acyl isothiocyanates has also been reported 112). The products are the corresponding carboxamides. The products from the isothiocyanates have been utilized as intermediates in the preparation of various heterocyclic compounds 113). 

The treatment of enamines with acid halides which possess no a hydrogens results in the simple acylation of the enamine (7,12,62-67). If the acid halide possesses an a hydrogen, however, ketenes are produced in situ through base-catalyzed elimination of hydrogen chloride from the acid halide. The base catalyst for this reaction may be the enamine itself or some other base introduced into the reaction mixture such as triethylamine. However, if the ketene is produced in situ instead of externally, there still remains the possibility of a side reaction between the acid halide and the enamine other than the production of ketene (67,84). 

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). 

This is illustrated by the reaction of enamine, 113 with sulfene to produce adduct 114 in an 80 % yield (146). The product 114 was also observed in an 18% yield from the reaction of diazomethane, sulfur dioxide, and enamine 113 (153). It was demonstrated that this cyclization reaction must involve sulfene adding to the enamine directly and not acylation of the enamine by... 

Alkylation of enamines with epoxides or acetoxybromoalkanes provided intermediates for cyclic enol ethers (668) and branched chain sugars were obtained by enamine alkylation (669). Sodium enolates of vinylogous amides underwent carbon and nitrogen methylation (570), while vicinal endiamines formed bis-quaternary amonium salts (647). Reactions of enamines with a cyclopropenyl cation gave alkylated imonium products (57/), and 2-benzylidene-3-methylbenzothiazoline was shown to undergo enamine alkylation and acylation (572). A cyclic enamine was alkylated with methylbromoacetate and the product reduced with sodium borohydride to the key intermediate in a synthesis of the quebrachamine skeleton (57i). 

The formation of an enamine from an a,a-disubstituted cyclopentanone and its reaction with methyl acrylate was used in a synthesis of clovene (JOS). In a synthetic route to aspidospermine, a cyclic enamine reacted with methyl acrylate to form an imonium salt, which regenerated a new cyclic enamine and allowed a subsequent internal enamine acylation reaction (309,310). The required cyclic enamine could not be obtained in this instance by base isomerization of the allylic amine precursor, but was obtained by mercuric acetate oxidation of its reduction product. Condensation of a dihydronaphthalene carboxylic ester with an enamine has also been reported (311). 

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