Esters, conjugated, reaction with metal amides

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. 

Aziridines can add to carbon—carbon multiple bonds. Elevated temperature and alkali metal catalysis are required in the case of nonpolarized double bonds (193—195). On the other hand, the addition of aziridines onto the conjugated polarized double or triple bonds of a,p-unsaturated nitriles (196—199), ketones (197,200), esters (201—205), amides (197), sulfones (206—209), or quinones (210—212) in a Michael addition-type reaction frequendy proceeds even at room temperature without a catalyst. The adducts obtained from the reaction of aziridines with a,p-unsaturated ketones, eg, 4-aziridinyl-2-butanone [503-12-8] from 3-buten-2-one, can be converted to 1,3-substituted pyrrolidines by subsequent ring opening with acyl chlorides and alkaline cyclization (213). 

Many other examples of chemoselective enone reduction in the presence of other reducible functionalities have been reported. For instance, the C—S bonds of many sulfides and thioketals are readily cleaved by dissolving metals. " Yet, there are examples of conjugate reduction of enones in the presence of a thioalkyl ether group." " Selective enone reduction in the presence of a reducible nitrile group was illustrated with another steroidal enone. While carboxylic acids, because of salt formation, are not reduced by dissolving metals, esters" and amides are easily reduced to saturated alcohols and aldehydes or alcohols, respectively. However, metal-ammonia reduction of enones is faster than that of either esters or amides. This allows selective enone reduction in the presence of esters"" and amides - -" using short reaction times and limited amounts of lithium in ammonia. 

Bransted LFER. Bronsted and Pederson (1923) were the first to describe a relationship between rates and equilibria for a series of compounds. They found that log/cB for base-catalyzed decomposition of nitramide, H2N202, varies linearly with log/CHB+, the acidity constant of the conjugate acid of the catalyst. Rate constants for many other acid- or base-catalyzed reactions (including the hydrolysis of amides, esters, carbamates, and organophosphates, and dissociation of acids and metal-ion complexes) are log-log related to the acid (or base) dissociation constant of the catalyst and follow either of the equations... 

For acylations with reactive esters, such as formate or oxalate (see Section 3.6.4.5), sodium alkoxides are still the bases of choice, but sodium hydride, dimsyl sodium, sodium or potassium amide or sodium metal have all been used for the in situ generation of the enolate anion. A typical example is shown in Scheme 47. Acylation by esters results in the production of 1 equiv. of the alkoxide ion, along with the p-dicarbonyl compound proton transfer then results in the production of the conjugate base of the dicarbonyl compound. This process normally leads to the more stable anion in the acylation of an unsymme-trical ketone. The acyl group thus becomes attached to the less-substituted a-position of the ketone. The less stable 0-acylated products are normally not observed in such reversible base-catalyzed reactions. Methyl alkyl ketones are normally acylated on the methyl group where both a-carbons are substituted to the same extent, acylation occurs at the less-hindered site. Acylation is observed only rarely at a methine carbon as the more stable p-diketone enolate cannot be formed. 

In conjugate reduction of enones with other transition metals such as chromium, the rates of reduction were shown to be dependent on the conformation of the substrate, with faster reactions being observed with the cisoid forms as compared with the transoid onesJ However, with the Pd/Si/Zn system, the rigid transoid enone of cyclohexenone and the flexible enone of acetylcyclohexene are both reduced in comparable rates. This indicates that palladium interacts exclusively with the olefinic part of the enone without significant participation of the carbonyl. Interestingly, this method is highly selective for unsaturated ketones and aldehydes, as the reduction of corresponding o,jS-unsaturated carboxylic acid derivatives, such as esters, amides, and nitriles, is very slow under the conditions used. Thus, ben-zylideneacetone is selectively and cleanly reduced in the presence of methyl cinnamate, dnnamonitrile, or dnnamamide.t" ... 

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