In the Michael addition

Second, an enamine from a mowoketone can be used in the Michael addition, whereas enoJate ions only from fi-dicarbonyl compounds can be used. 

Strategy The overall result of an enamine reaction is the Michael addition of a ketone as donor to an cr,/3-unsaturated carbonyl compound as acceptor, yielding a 1,5-dicarbonyl product. The C—C bond made in the Michael addition step is the one between the a- carbon of the ketone donor and the /3 carbon of the unsaturated acceptor. 

In the Michael addition of achiral enolates and achiral Michael acceptors the basic general problem of simple diastereoselection (see Section D.1.5.1.3.2.), as described in Section 1.5.2.3.2. is applicable. Thus, the intermolecular 1,4-addition of achiral metal enolates to enones, a.jS-unsat-urated esters, and thioamides, results in the formation of racemic syn-1,2 and/or anti-3,4 adducts. 

When chiral enolates or chiral Michael acceptors are used, for instance, when stereogenic centers are present in the substrate or when X or Y are chiral auxiliaries, both simple and induced diastereoselectivity is observed. This results, in principle, in the formation of four diastereomers 1 -4. The diastereoselectivity in the Michael addition of lithium enolates to enones can be rationalized by consideration of chelated transition states A-D372. 

Under thermodynamically controlled conditions, using triethylamine as base for the addition of enones to 5 and sodium methoxide in methanol as base for the addition of a,/ -unsaturated esters, the diastereomeric ratios of 6 range from 95 5 to 97 3. The excellent diasteroselectivities are retained in the Michael addition of 5 to -substituted enones and esters, however, modest synjami selectivities are found212,213. 

Another interesting example is provided by the phenylethynylcarbene complex 173 and its reactions with five-, six-, and seven-membered cyclic enamines 174 to form bridgehead-substituted five-, six-, and seven-membered cycloalkane-annelated ethoxycyclopentadienes with high regioselectivity under mild reaction conditions (Scheme 38) [119,120]. In these transformations the phenylethynylcarbene complex 173 acts as a C3 building block in a formal [3+2] cycloaddition. Like in the Michael additions (reaction route F in Scheme 4), the cyclic electron-rich enamines 174 as nucleophiles attack the... 

In the synthesis of N heterocycles, this technique also overcomes competitive retro Michael addition that lowers the yield of 1,4-adduct in the Michael addition of amines to nitro olefins. Thus, a toluene solution of nitro olefin 159 was treated with allylamine 160, EtgN, and TMSCI under nitrogen at ambient tern-... 

A short enantioselective synthesis of (-)-(R,R)-pyrenophorin, a naturally occurring anti-fun-gal 16-membered macrolide dilactone, is prepared from (S)-5-nitropentan-2-ol via the Michael addition and Nef reaction (Scheme 4.23).162 The choice of base is important to get the E-alkene in the Michael addition, for other bases give a mixture of E and Z-alkenes. The requisite chiral (S)-5-nitropentan-2-ol is prepared by enantioselective reduction of 5-nitropentan-2-one with baker s yeast.163... 

Catalytic enantioselective nucleophilic addition of nitroalkanes to electron-deficient alke-nes is a challenging area in organic synthesis. The use of cinchona alkaloids as chiral catalysts has been studied for many years. Asymmetric induction in the Michael addition of nitroalkanes to enones has been carried out with various chiral bases. Wynberg and coworkers have used various alkaloids and their derivatives, but the enantiomeric excess (ee) is generally low (up to 20%).199 The Michael addition of methyl vinyl ketone to 2-nitrocycloalkanes catalyzed by the cinchona alkaloid cinchonine affords adducts in high yields in up to 60% ee (Eq. 4.137).200... 

Chiral monoaza-crown ethers containing glucose units have been applied as phase-transfer catalysts in the Michael addition of 2-nitropropane to a chalcone to give the corresponding adduct in up to 90% ee. (Eq. 4.138).202... 

Synthesis of isomeric chiral protected (63 )-6-amino-hexahydro-2,7-dioxopyrazolo[l,2- ]pyrazole-l-carboxylic acid 280 is shown in Scheme 36. Crude vinyl phosphonate 275, obtained by treatment of diethyl allyloxycarbonylmethyl-phosphonate with acetic anhydride and tetramethyl diaminomethane as a formaldehyde equivalent, was used in the Michael addition to chiral 4-(f-butoxycarbonylamino)pyrazolidin-3-one 272. The Michael addition is run in dichloro-methane followed by addition of f-butyl oxalyl chloride and 2 equiv of Huning s base in the same pot to provide 276 in 58% yield. The allyl ester is deprotected using palladium catalysis to give the corresponding acid 277, which is... 

In the Michael addition reaction depicted in eq. [146] the diastereomeric sulfoxides 312 are formed under kinetic control conditions, therefore, the addition of sodium diethyl malonate is an irreversible process. On the contrary, addition of sodium methoxide to the sulfoxide 311 is a thermodynamically controlled process and leads to a mixture of diastereomeric ]3-methoxysulfoxides 313 in a 31 69 ratio (320). 

Typical acceptors in Michael additions are reducible and their radical anions often undergo dimerization (hydrodimerizations). Either the radical anions or more likely the dimer dianions can act as EGBs toward the donor in the Michael addition. Since the reaction is catalytic in base when the product anion is more basic than the donor anion, the Michael addition can take place by reduction of a small fraction (2-10%) of the acceptor [129]. The reaction takes place in 20 to 77% yield... 

In the Michael addition reaction of (S )-phenylethylamine and L-alanine isopropyl ester to [Pg.444]

Furthermore, to clarify the difference between task specific ionic hquids (or also called functionahzed ionic hquids) and chiral ionic hquids, one very successful example of a task specific ionic hquid 63 is presented in Scheme 65. This catalyst with a loading of 15 mol% under neat conditions gave up to 100% yield and 99% ee in the Michael addition of cyclohexanones to nitroolefms [179]. This catalyst belongs to the field of the prohne catalyzed reactions. 

The chiral ionic liqnids 68 and 69 were tested in the Michael addition (Scheme 72) [194],... 

Scheme 6.65 Mechanistic proposals for the biflinctional mode of action of catalyst 12 in the Michael addition of thioacetic acid to nitroalkenes (A) and to chalcones (B).

Figure 6.27 Representative (R,R)-l,2-diaminocyclohexane-derived thiourea derivatives incorporating a phthalimide (Phthal) and tetraphenylphthalimide (TPhP) moiety catalyst screening was performed in the Michael addition of acetophenone-derived morpholine enamine to trans-()-nitrostyrene in toluene as the solvent.

The Chen group early in 2005 constituted the novel class of thiourea-function-ahzed cinchona alkaloids with the first reported synthesis and application of thioureas 116 (8R, 9S) and 117 (8R, 9R) prepared from cinchonidine and cinchonine in over 60% yield, respectively (Scheme 6.112) [273]. In the Michael addition of thiophenol to an a,(5-unsaturated imide, the thioureas 116 and 117 displayed only poor stereoinduction (at rt 116 7% ee 117 17% ee), but high catalytic activity (99% yield/2h) (Scheme 6.112). 

Figure 6.39 Cinchona alkaloid-thioureas prepared from quinine (121), dihydroquinine (122), C9-epi-quinine (123), and quinidine (124) catalytic efficiency evaluated in the Michael addition of nitromethane to tram-chalcone 1,3-diphenyl-propenone at 10mol% loading and rt.

Figure 6.47 Various thiourea catalysts screened in the Michael addition of O-benzylhydroxylamine to 2,4-dimethyl pyrazole crotonate.

In the Michael addition of the ( -cnethiolatc to ( )-3-penten-2-one, the reaction occurs at a center that is prostereogenic in each of the two achiral reactants. One (racemic) diastereomer is formed as the main adduct (see pp469 and 472 for the determination of configuration)8-89. 

Instead of introducing the (S)-proline-derived chiral auxiliary (206), its enantiomer in the Michael-addition, the authors obtained the enantiomeric product (208 ) having opposite optical rotation compared to (208). 

Often, the basic group that is responsible for the proton abstraction is also the nucleophilic group in the Michael addition. Thus, most of the suicide inhibitors made so far have been aimed at enzymes that catalyze the formation of carban-ions or carbanion-like intermediates. Suicide inhibitors are typically based on acetylenic compounds (as in equation 9.8), /3, y-unsaturated compounds (as in equation 9.9), or /3-halo compounds (as in equation 9.10). (The a protons in such compounds are acidic because the negative charge in the carbanion is delocalized by the conjugation with X.)... 

Michael addition may then take place at the terminus of the conjugated system. Lysine-258 at the active site is alkylated by the suicide inhibitor. The reaction is similar to that of equation 9.7, except that in the Michael addition the pyridoxal ring acts as the electron sink, rather than the N atom originating from the vinyl glycine. 

The chiral, nonracemic oxazepine derivative (46 Scheme 18) was studied as donor in the Michael addition to prochiral a,p-unsaturated carbonyl compounds.134-133 The products were obtained with 44-55% ee after removal of the chiral auxiliary group. With 1-nitrocyclohexene as acceptor, somewhat better se-lectivities (62% ee) were observed.136... 

Both regioselectivity and enantioselectivity are efficiently controlled by ALB in the Michael addition of Horner-Wadsworth-Emmons reagents 17 with enones (Scheme 8D.12) [29]. Although the reaction catalyzed by ALB itself did not afford the product, the use of a combination of ALB (10 mol %) and NaC/Bu (0.9 equiv. to ALB) gave the Michael adduct of 17 to cyclohexenone in 64% yield and 99% ee. The reaction of cyclohexenone with 17 promoted by standard bases such as NaO Bu and BuLi gave the 1,2-adduct in only 8-9% yield. The adduct... 

Regioselectivity in the Michael addition of nitromethane to x/i-unsaturatcd esters in the presence of Triton B has been studied both theoretically and experimentally.87... 

These anthracene-linked dimeric PTCs (42-53) were also employed in the Michael addition reaction of 1 by the Najera group (Scheme 4.11) [18], Depending on the Michael acceptor and the nature of the counter anion part of the ammonium cation in PTC, a variation of both chemical yield and stereoselectivity was observed. 

Recently, Maruoka and coworkers addressed the importance of dual-functioning chiral phase-transfer catalysts such as 70a for obtaining a high level of enantio-selectivity in the Michael addition of malonates to chalcone derivatives (Scheme 5.35) [37]. For instance, the reaction of diethyl malonate with chalcone in... 

In the Michael-addition, a nucleophile Nu is added to the / -position of an a,fi-unsaturated acceptor A (Scheme 4.1) [1], The active nucleophile Nu is usually generated by deprotonation of the precursor NuH. Addition of Nu to a prochiral acceptor A generates a center of chirality at the / -carbon atom of the acceptor A. Furthermore, the reaction of the intermediate enolate anion with the electrophile E+ may generate a second center of chirality at the a-carbon atom of the acceptor. This mechanistic scheme implies that enantioface-differentiation in the addition to the yfi-carbon atom of the acceptor can be achieved in two ways (i) deprotonation of NuH with a chiral base results in the chiral ion pair I which can be expected to add to the acceptor asymmetrically and (ii) phase-transfer catalysis (PTC) in which deprotonation of NuH is achieved in one phase with an achiral base and the anion... 

The best selectivity in the Michael addition of 2-carboxycyclopentanones to an enone or enal were recently achieved by Maruoka et al. [9]. As shown in Scheme 4.5, as little as 2 mol% of the binaphthyl-derived phase-transfer catalyst 10 - in the presence of 10 mol% solid potassium carbonate - enabled the highly efficient... 

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