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Addition reactions, Michael, catalytic asymmetric

Acrylonitrile, polymerization, 120 Activity of phase-transfer catalysts Sjj2 reactions, 170-175 weak-nucleophile Sj.Ar reactions, 175-182 Acyltetracarbonyl cobalt compound, cleavage in the carboxyalkylation of alkyl halides, 150 Addition reactions, Michael, catalytic asymmetric, 69,70f... [Pg.186]

Heterobimetallic asymmetric complexes contain both Bronsted basic and Lewis acidic functionalities. These complexes have been developed by Shibasaki and coworkers and have proved to be highly efficient catalysts for many types of asymmetric reactions, including catalytic asymmetric nitro-aldol reaction (see Section 3.3) and Michael reaction. They have reported that the multifunctional catalyst (f )-LPB [LaK3tris(f )-binaphthoxide] controls the Michael addition of nitromethane to chalcones with >95% ee (Eq. 4.140).205... [Pg.119]

For example, an effective procedure for the synthesis of LLB (where LL = lanthanum and lithium) is treatment of LaCls 7H2O with 2.7 mol equiv. BINOL dilithium salt, and NaO-t-Bu (0.3 mol equiv.) in THF at 50 °C for 50 h. Another efficient procedure for the preparation of LLB starts from La(0-/-Pr)3 [54], the exposure of which to 3 mol equiv. BINOL in THF is followed by addition of butyllithium (3 mol equiv.) at 0 C. It is worthy of note that heterobimetallic asymmetric complexes which include LLB are stable in organic solvents such as THF, CH2CI2 and toluene which contain small amounts of water, and are also insensitive to oxygen. These heterobimetallic complexes can, by choice of suitable rare earth and alkali metals, be used to promote a variety of efficient asymmetric reactions, for example nitroaldol, aldol, Michael, nitro-Mannich-type, hydrophosphonylation, hydrophosphination, protonation and Diels-Alder reactions. A catalytic asymmetric nitroaldol reaction, a direct catalytic asymmetric aldol reaction, and a catalytic asymmetric nitro-Mannich-type reaction are discussed in detail below. [Pg.932]

A catalytic asymmetric amination reaction has been developed using Cu(2+) catalysts (246). The azodicarboxylate derivative 392 reacts with enolsilanes in the presence of catalyst 269c to provide the adducts in high enantioselectivity, Eq. 213. As observed in the Mukaiyama Michael reactions, alcoholic addends proved competent in increasing the rate of this reaction. Indeed, in the presence of tri-fluoroethanol as additive, the reaction time decreases from 24 to 3 h. [Pg.127]

The Michael reactions [149-152] between cyclohexanone and trons-nitroalkenes were also explored by Xiao and co-workers utilizing bifunctional pyrrolidine-thiourea 213 and the pyrrolidine-thioureas 214-217 (Figure 6.61) [344]. The model Michael reaction between cyclohexanone and trons-nitrostyrene identified water as the best solvent and 217 to be the most efficient catalysts concerning the activity and asymmetric induction (90% yield 96% ee dr 98 2 in 12 h at 35 °C) in the presence of benzoic acid (10mol%) as additive. The optimized catalytic system allowed the formation of a broad spectrum of Michael adducts such as 1-6 resulting from... [Pg.326]

Significant improvement in the catalytic activity of ALB was realized without any loss of enantioselectivity by using the second-generation ALB [27] generated by the self-assembled complex formation of ALB with alkali metal-malonate or alkoxide. This protocol allowed the catalyst loading to be reduced to 0.3 mol %, for example, the Michael addition of methyl malonate to cyclohexenone catalyzed by the self-assembled complex of (ff)-ALB (0.3 mol %) and KO Bu (0.27 mol %) in the presence of MS 4A gave the adduct in 94% yield and 99% ee [28]. This reaction has been successfully carried out on a 100-g scale wherein the product was purified by recrystallization. The kinetic studies of the reactions catalyzed by ALB and ALB/Na-malonate have revealed that the reactions are second-order to these catalysts (the rate constant ALB = 0.273 M 1h 1 ALB/Na-maionate = 1-66 M 1h 1) [27]. This reaction was used as the first key step for the catalytic asymmetric total synthesis of tubifolidine (Scheme 8D. 11) [28]. [Pg.581]

Other reviews deal with aldol additions of group 1 and 2 enolates,103 direct catalytic asymmetric aldol reactions catalysed by chiral metal complexes,104 the exploitation of multi-point recognition in catalytic asymmetric aldols,105 and recent progress in asymmetric organocatalysis of aldol, Mannich, Michael, and other reactions.106... [Pg.12]

The synthesis of the optically active chroman 489 can be achieved by use of a catalytic asymmetric tandem oxa-Michael addition Friedel-Crafts alkylation sequence between 3-methoxyphenol and (/. (-methyl 2-oxo-4-phenylbut-3-enoate. The chiral C2-symmetric box managanese(n)- complex 490 exerts excellent stereocontrol upon the reaction (Equation 200) <20030BC1953>, whereas only moderate enantioselectivity is observed in the presence of a chiral C2-symmetric 2,2 -bipyridyl copper(n)- complex (42% = ee) <20050L901>. [Pg.520]

The third part of this chapter reviews previously described catalytic asymmetric reactions that can be promoted by chiral lanthanoid complexes. Transformations such as Diels-Alder reactions, Mukaiyama aldol reactions, several types of reductions, Michael addition reactions, hydrosilylations, and hydroaminations proceed under asymmetric catalysis in the presence of chiral lanthanoid complexes. [Pg.202]

Implied in the stoichiometry of their preparation is the full equivalent of transition metal relative to substrate. Indeed, to this day, cuprates tend to be used in excess in most smaller scale reactions. Over the past decade, however, there has been a noticeable shift toward development of methodology catalytic in Cu(I). The rationale behind the emphasis is in line with the times that is, environmental concerns have come to the fore, placing implied limits on the extent of transition metal usage. Therefore, notwithstanding favorable economic factors associated with copper, it being a base rather than precious metal, much effort has been devoted toward copper-catalyzed reactions, including cross-couplings to arrive at C-N, C-O, and C-H, in addition to C-C bonds. Moreover, tremendous strides have been made in asymmetric versions of perhaps the most fundamental of cuprate reactions 1,4-additions to Michael acceptors. [Pg.960]

The Lewis acid-catalyzed conjugate addition of silyl enol ethers to a,y3-unsaturated carbonyl derivatives, the Mukaiyaraa Michael reaction, is known to be a mild, versatile method for carbon-cabon bond formation. Although the development of catalytic asymmetric variants of this process provides access to optically active 1,5-dicarbonyl synthons, few such applications have yet been reported [108], Mukiyama demonstrated asymmetric catalysis with BINOL-Ti oxide prepared from (/-Pr0)2Ti=0 and BINOL and obtained a 1,4-adduct in high % ee (Sch. 43) [109]. The enantioselectiv-ity was highly dependent on the ester substituent of the silyl enol ether employed. Thus the reaction of cyclopentenone with the sterically hindered silyl enol ether derived from 5-diphenylmethyl ethanethioate proceeds highly enantioselectively. Sco-lastico also reported that reactions promoted by TADDOL-derived titanium complexes gave the syn product exclusively, although with only moderate enantioselectiv-ity (Sch. 44) [110]. [Pg.825]

The first prominent catalytic asymmetric Michael-type addition reaction of an organolithium reagent was shown by the reaction of 1-naphthy[lithium with 1-fluoro-2-naphthylaldehyde imine in the presence of 6 to afford the binaphthyls in high ee. Only catalytic amounts of 6 (0.05 mol%) effects the reaction to give 82% ee, in which an enantioselective Michael-type addition-elimination mechanism is operative (Eq. (12.12)) [31],... [Pg.495]

A number of phosphonate and phosphinate derivatives where the phosphorus atom is directly bonded to non-aromatic cyclic systems have been reported. The synthesis and reactions of a number of compounds with the general structure 103 have been reported. Enantiomerically pure cyclopropanephosphonic acids which are constrained analogues of the GABA antagonist phaclophen, have been prepared by stereocontrolled Michael addition of a-anions derived from chiral chloromethylphosphonamides 104 to a,P-unsaturated esters followed by in situ cyclisation. Other asymmetric syntheses include those of (/ )- and (S)-piper-idin-2-ylphosphonic acid (105) via the addition to trialkyl phosphites to iminium salt equivalents and 4-thiazolidinylphosphonate 106 by catalytic asymmetric hydrophosphonylation of 3-thiazoline. In the latter case both titanium and lanthanoid (which give much better e.e. values) chiral catalysts are used. [Pg.112]

When the Michael donors have a sufficiently low pKa, the Michael addition can be catalyzed by a base. The first catalytic asymmetric conjugate addition was achieved by Wynberg et al. in 1975 using cinchona bases [la]. They performed the reaction of cyclic P-ketoesters such as 1 with methyl vinyl ketone in the presence of quinine and... [Pg.249]

For the asymmetric synthesis of the 2-substituted chromane 7 via the intramolecular Michael addition reaction of 6, Merschaert et al. also employed natural cinchona alkaloids such as HCD as catalysts (Scheme 9.3) [3]. Here again, the 9-0 functionalization and dehydroxylation of the natural alkaloid showed a large negative effect, indicating that the presence of the 9-OH group is needed to achieve both good kinetics and enantioselectivity. Moreover, C3 modifications of this parent alkaloid did not lead to any significant improvement in the results in terms of the enantioselectivity and catalytic activity. [Pg.251]

With regard to the catalytic asymmetric reaction , only a few successful examples, except those reactions using chiral transition metal complexes, have been reported. For example, the cinchona-alkaloid-catalyzed asymmetric 1,4-addition of thiols or 6-keto esters to Michael acceptors quinidine catalyzed the asymmetric addition of ketene to chloral and the highly enantioselective 1,4-addition of ) -keto esters in the presence of chiral crown ethers to Michael acceptors have been most earnestly studied. [Pg.159]

Conjugate addition reactions are some of the most fundamental C-C bondforming reactions in organic synthesis, and their asymmetric versions have been studied extensively [ 1 ]. Treated in this chapter is the catalytic conjugate addition of stabihzed carbanions, especially enolate derivatives, for which the term Michael addition and/or reaction is used. The asymmetric Michael reactions can be categorized into two groups (Fig. 1) ... [Pg.1058]

Several successful examples appeared for the catalytic asymmetric Michael addition reaction. It may be apparent, however, that they are not yet quite satisfactory in terms of stereoselectivity, catalyst efficiency, and applicability. Development of new methods is still required, which would also deepen the fundamental understanding of the Michael addition reaction, a very important reaction in organic synthesis. [Pg.1075]

Hetero-Diels-Alder reactions of l-oxa-l,3-butadienes with vinyl ethers, which lead to 3,4-dihydro-2H-pyran derivatives, are synthetically equivalent to Michael type conjugate additions. Wada and coworkers presented the first examples of a catalytic asymmetric intermolecular hetero-Diels-Alder reaction by the use of ( )-2-oxo-l-phenylsulfonyl-3-alkenes 25 and vinyl ethers 26 (Table 3) [25]. [Pg.1177]

Aza-Henry reaction is rendered asymmetric by quaternary salts of Cinchona alkaloids. Addition reactions. Changing the 9-hydroxy group of Cinchona alkaloids to a 9-epiamino group not only is synthetically expedient, such products often show excellent catalytic activities in many asymmetric reactions. Those derived from dihydrocinchona alkaloids mediate Michael reactions to good results, including addition of indole to enones, and carbonyl compounds to nitroalkenes. Salt 4 has also been successfully employed in the alkenylation of t-butyl a-aryl-a-cyanoacetate. ... [Pg.171]

One important characteristic of the Michael addition reaction is that when the donor and acceptor contain suitably different substituents, one or two new chiral centers can be created, producing one or two pairs of enantiomers. When, on the other hand, either or both of the reactants has a chiral substituent, the reaction can be enantioselective. Enantioselective addition has also been achieved by use of chiral catalysts [2], Indeed, it is interesting to remark that in recent years much attention has been devoted to catalytic asymmetric Michael reactions because of the importance of the products as optically active intermediates for many functional compounds [30] many types of chiral catalyst have been reported [31],... [Pg.312]


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See also in sourсe #XX -- [ Pg.69 , Pg.70 ]




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