Michael acceptors unsaturated amides

Rovis and co-workers have also shown that pre-catalyst 129 is competent with a wide range of Michael acceptors including oc,P-unsaturated aldehydes, amides, nitriles, esters, thioesters, vinylphosphonates and vinylphosphine oxides (Scheme 12.25) [58,60],... 

During the coverage period of this chapter, reviews have appeared on the following topics reactions of electrophiles with polyfluorinated alkenes, the mechanisms of intramolecular hydroacylation and hydrosilylation, Prins reaction (reviewed and redefined), synthesis of esters of /3-amino acids by Michael addition of amines and metal amides to esters of a,/3-unsaturated carboxylic acids," the 1,4-addition of benzotriazole-stabilized carbanions to Michael acceptors, control of asymmetry in Michael additions via the use of nucleophiles bearing chiral centres, a-unsaturated systems with the chirality at the y-position, and the presence of chiral ligands or other chiral mediators, syntheses of carbo- and hetero-cyclic compounds via Michael addition of enolates and activated phenols, respectively, to o ,jS-unsaturated nitriles, and transition metal catalysis of the Michael addition of 1,3-dicarbonyl compounds. ... 

The alternative strategy of using d,v-aminoindanol as a chiral auxiliary on the Michael donor has also been explored.81 Chiral amide enolates were reacted with a,P-unsaturated ester 70, and the resultant adducts were reduced and cyclized to 8-lactones 73 to determine the facial selectivity on the Michael acceptor. It is interesting that protected amino alcohol 71 did not lead to significant diastereofacial discrimination, whereas 72 afforded lactone 73 with high 4-(,S )-selectivity (Scheme 24.15). 

Unsaturated ketones and amides are not successful traps for alkyllithiums, and the only other activated alkene to have successfully trapped an alkyllithium is the unsaturated phosphorane 175.85 This trap works remarkably well with both vinyl and alkyl iodides, giving good yields of ring sizes 3-6, and is not perturbed even by a second substituent on the Michael acceptor, as in 176. 

The synthesis was most efficient with an unsaturated amide as Michael acceptor,... 

Michael acceptor groups other than a,p-unsaturated esters give only traces of cyclized products under similar conditions. The major products result from 1,2- and 1,4-additions of n-butyllithium in the case of co-iodo-a,(3-unsamrated ketones or 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. 

The reaction of Michael acceptors with dimethyloxosulfonium methanide has been extensively explored.3 4,111 112 115 In addition to carbene (or carbenoid) additions (Section 1.2.1.) and the Simmons-Smith method,114 (see also Section 1.2.1.1,) this is the most widely utilized method for the introduction of a cyclopropane ring, in good to excellent yield, to a,/J-unsaturated ketones,120- 126 esters118 120,122,128 - 130,132 amides,118,119 133 nitriles,1l8-119,126 isonit-... 

Unsaturated esters are good Michael acceptors because they are not very electrophilic. Unsaturated amides are even less electrophilic and (provided they are tertiary and have no acidic NH protons) will even give conjugate addition products with lithium enolates. 

Intramolecular asymmetric Stetter reactions enjoy a range of acceptable Michael acceptors and acyl anion precursors. These reactions can utilize aromatic, heteroaromatic, and aliphatic aldehydes with a tethered a,p-unsaturated ester, ketone, thioester, malonate, nitrile, or Weinreb amide. In this part, we will give a brief summary about asymmetric intramolecular Stetter reactions and selected recent results in this area (Scheme 7.17). 

With respect to the substrate scope, ketones are the most efficient nucleophiles although the intermolecular reaction works also well for esters, amides and Weinreb amides (Fig. 2.7). Regarding the Michael acceptor, enones are the best electrophiles with a wide range of substituents tolerated (alkyl, aryl and heteroaryl ketones). a,p-Unsaturated esters, in the case of the intermolecular cyclopropanation, and a,p-unsaturated diimides for the intramolecular reaction, extends the substrate scope of the process (Fig. 2.7). A transition state model for the intramolecular cyclopropanation reaction has been proposed as depicted in Scheme 2.38 for catalyst 65 [106d]. In this model the ammonium salt adopts a conformation that gives the Z-enolate of the nucleophile on deprotonation with the base. The intramolecular conjugate addition of the enolate then takes place through a boat-type transition state. 

Other electrophiles, such as Michael acceptors, can also be involved in the a-alkylation step. This has been exploited in the conjugate addition of enantiopure lithium amides 60 to unsaturated esters 61, followed by trapping of the resulting enolate with alkylidene malonates. This constitutes a useful methodology for the asymmetric synthesis of p-amino-a-substituted carboxylic acid derivatives 62 (Scheme 11.24) [65]. 

Hayashi and Miyaura pioneered the enantioselective rhodium-catalyzed conjugate addition of arylboronic acids to a variety of Michael acceptors a,P-unsaturated ketones, esters, lactones, amides, and lactams [215]. Generally, water is used as a cosolvent and plays a key role in the catalytic cycle, illustrated in Scheme 5.111 (cycle A) for the conjugate addition of phenylboronic acid to cyclohexenone that, when catalyzed by the Rh(I)-(S)-BINAP complex, leads to 3-phenylcyclohexanone in 97% ee and 93% chemical yield [205a]. The key intermediates of the catalytic cycle, the hydroxorhodium complex 433, the phenylrhodium complex 434, and -bound rhodium enolate 435 were characterized by NMR spectroscopy. The reaction of the hydrorhodium complex 433 with phenylboronic acid leads to a transmetallation to give the phenylrhodium complex 434. Then, the insertion of the carbon-carbon double bond of cyclohexenone into the phenylrhodium bond leads to the formation of the... 

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