Michael-Claisen reactions

The addition of dialkyl [2- " C]malonates to acyclic a,/3-unsaturated ketones has been used more frequently in carbon-14 synthesis. The resulting primary adducts spontaneously cyclize in a tandem Michael-Claisen reaction to give 6-substituted 4-hydroxy-2-oxo[l- " C]cyclohex-l-encarboxylate esters 367. The ester function can be readily split off... 

Figure 6.110 Generic depiction of Michael-Claisen reactions with [2d C]malonates...

Figure 6.111 Examples of [2- C]malonate Michael-Claisen reactions in synthesis...

There are a number of powerful synthetic reactions which join two trigonal carbons to form a CC single bond in a stereocontrolled way under proper reaction conditions. Included in this group are the aldol, Michael, Claisen rearrangement, ene and metalloallyl-carbonyl addition reactions. The corresponding transforms are powerfully stereosimplifying, especially when rendered enantioselective as well as diastereoselective by the use of chiral controller groups. Some examples are listed in Chart 20. 

The intramolecular carbon-carbon bond-forming reactions considered in this section are based on the aldol condensation (see Section 5.18.2, p. 799), the Claisen-Schmidt reaction (see Section 6.12.2, p. 1032), the Claisen ester condensation (see Section 5.14.3, p. 736), and the Claisen reaction (see Section 6.12.2, p. 1032). Since these carbonyl addition reactions are reversible, the methods of synthesis are most successful for the formation of the thermodynamically stable five- and six-membered ring systems. The preparation of the starting materials for some of these cyclisation reactions further illustrates the utility of the Michael reaction (see Section, 5.11.6, p. 681). 

When you need to synthesize a p-hydroxy ketone or aldehyde or an a,p-unsaturated ketone or aldehyde, use an aldol reaction. When you need to synthesize a p-diketone or p-keto ester, use a Claisen reaction. When you need to synthesize a 1,5-dicarbonyl compound, use a Michael reaction. The Robinson annulation is used to synthesize polycyclic molecules by a combination of a Michael reaction with an aldol condensation. 

An asymmetric total synthesis of (—)-secodaphniphylline was carried out using a mixed Claisen condensation between (—)-methyl homosecodaphniphyllate (11) and a carboxylic acid derivative 154 with the characteristic 2,8-dioxabicyclo[3.2.1]octane structure commonly found in the daphniphyllum alkaloids (Scheme 18.23) [68,69]. The necessary chirality was secured by an asymmetric Michael addition reaction of... 

Like the aldol and Claisen reactions, the Michael reaction involves tvro carbonyl components-the enolate of one carbonyl compound and an o,P-unsaturated carbonyl compound. 

Carbanions frequently add to the carbonyl double bond. The aldol reaction, Claisen reaction, Dieckmann reaction, Michael reaction, and Knoevenagel condensation are familiar examples of carbanions (as enolates) undergoing nucleophilic addition to carbon-oxygen double bonds. 

Tandem Michael—Dieckmann/Claisen reaction of ortho-toluates The Staunton—Weinreb annulations 13T3747. 

Reaction of enolate anions with a,)8-unsaturated carbonyl species in Michael reactions gives products with oxygen atoms positioned in a 1,5 arrangement, which is distinct from the 1,3 positioning seen in aldol and Claisen reactions. 

The sequential Michael addition/Ireland-Claisen reactions proceed with high diastereoselectivity in one pot. Preparation of the lithium enolate 68 with LDA in THF at —78 °C followed by the addition of the allylic ester acceptor 67 leads to the smooth conjugate addition, whose stereoselectivity was more than 98% diastereomeric excess. The ketene silyl acetal 70, which was formed by the trapping of the Michael addition intermediate 69 with TMSCl, underwent Ireland-Claisen rearrangement in the presence of PdCl2(PhCN)2... 

This chapt er covered many C—C bond-forming reactions, including aldol reactions, Claisen condensations, and Michael addition reactions. Two or more of these reactions are often performed sequentially, providing a great deal of versatility and complexity in the type of stmctures that can be prepared. Propose a plausible mechanism for each of the following transformations. 

The Claisen reaction The crossed Claisen and related reactions The Dieckmann reaction The Michael reaction The Robinson annulation... 

Flavanones 25 are often synthesized by Claisen-Schmidt condensation followed by intramolecular Michael addition reaction of the corresponding chalcone derivative. Climent et al. reported a new environment-friendly method to prepare flavanones 25 by the reaction of 5-substituted-2-hydroxyacetophenones and benzaldehydes using hydro-talcites as basic catalysts (Scheme 16) [81]. Substitution over both aromatic rings influenced the reaction coxu-se leading to flavanones 25 in 7-45% of yields in only Ih of reaction time. 

Count your carbons I Get in the habit of counting the number of carbons in the starting material and making sure that all carbons ate accounted for in the products. Accidentally losing or gaining a carbon is very easy to do in an aldol or Claisen reaction, and especially in a Michael reaction. 

In the amine-catalyzed reactions, a Knoevenagel addition/ketalization/ intramolecular retro-Claisen cascade is detected (Scheme 2.32). The retro-Claisen step is enabled by the ketalization of the Knoevenagel addition product Q. The ketalization of the Knoevenagel product (Q S) is initiated by the hydroxyl groups of the carbohydrate moiety, as in-house NMR-experiments suggest (formation of intermediate ketal structure K in Knoevenagel condensation/ketalization/oxa-Michael cascade reaction Scheme 2.16). Products derived from this reaction sequence (Scheme 2.16)... 

Ba.se Catalyzed. Depending on the nature of the hydrocarbon groups attached to the carbonyl, ketones can either undergo self-condensation, or condense with other activated reagents, in the presence of base. Name reactions which describe these conditions include the aldol reaction, the Darzens-Claisen condensation, the Claisen-Schmidt condensation, and the Michael reaction. 

Even if organocatalysis is a common activation process in biological transformations, this concept has only recently been developed for chemical applications. During the last decade, achiral ureas and thioureas have been used in allylation reactions [146], the Bayhs-Hillman reaction [147] and the Claisen rearrangement [148]. Chiral organocatalysis can be achieved with optically active ureas and thioureas for asymmetric C - C bond-forming reactions such as the Strecker reaction (Sect. 5.1), Mannich reactions (Sect. 5.2), phosphorylation reactions (Sect. 5.3), Michael reactions (Sect. 5.4) and Diels-Alder cyclisations (Sect. 5.6). Finally, deprotonated chiral thioureas were used as chiral bases (Sect. 5.7). 

In a related example, reaction of N-hydroxy-N-methylthiophene-2-carboximidamide 56 with DMAD gave a double Michael addition product 57, which when heated at reflux in xylenes, afforded hydroxypyrimidinone 60 in 57% overall yield (Scheme 6.21) [9f]. The mechanism invoked was opening of the oxa-diazole 57 to 58, followed by a [3,3]-Claisen-type rearrangement to 59, which, after tautomerization and cyclization, afforded 60. 

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