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Lewis acids enantioselective Michael addition

The utilization of copper complexes (47) based on bisisoxazolines allows various silyl enol ethers to be added to aldehydes and ketones which possess an adjacent heteroatom e.g. pyruvate esters. An example is shown is Scheme 43[126]. C2-Symmetric Cu(II) complexes have also been used as chiral Lewis acids for the catalysis of enantioselective Michael additions of silylketene acetals to alkylidene malonates[127]. [Pg.32]

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]

This type of reaction attracted broad interest when it was discovered that high regioselectivity can also be effected with organoaluminum compounds and other nucleophiles in the presence of Lewis acids and that by employing chiral cyclic acetals (from optically active 1,2- or 1,3-diols) diastereoselective transformations can be realized. - Such reactions are synthetically very valuable when considering that the overall process represents an enantioselective Michael addition, where the chiral auxiliary can be recycled (Scheme 39). ... [Pg.849]

Itoh, K. and Kanemasa, S. (2002) Enantioselective Michael additions of nitromethane by a catal3ftic double activation method using chiral Lewis acid and chiral atitine catalysts. Journal of the American Chemical Society, 124, 13394—13395 Itoh, K., Oderaotoshi, Y. and Kanemasa, S. (2003) Enantioselective Michael addition reactions of malononitrile catalysed by chiral Lewis acid and achiral antine catalysts. Tetrahedron Asymmetry, 14, 635 39. [Pg.90]

This reaction was first reported by Mukaiyama et al. in 1974. It is a Lewis acid-catalyzed Michael conjugate addition of silyl enol ether to o ,/3-unsaturated compounds. Therefore, it is generally referred to as the Mukaiyama-Michael reaction. Because this reaction is essentially a conjugate addition, it is also known as the Mukaiyama-Michael addition or Mukaiyama-Michael conjugate addition. This reaction is a mechanistic complement for the base-catalyzed Michael addition, j and often occurs at much milder conditions and affords superior regioselectivity. s Besides silyl enol ether, silyl ketene acetals are also suitable nucleophiles in this reaction.For the hindered ketene silyl acetals, the Lewis acid actually mediates the electron transfer from the nucleophiles to o ,/3-unsaturated carbonyl molecules.On the other hand, the Q ,j8-unsaturated compounds, such as 3-crotonoyl-2-oxazolidinone, alkylidene malonates, and a-acyl-a,/3-unsaturated phosphonates are often applied as the Michael acceptors. It has been found that the enantioselectivity is very sensitive to the reactant structures —for example, Q -acyl-Q ,j8-unsaturated phosphonates especially prefers the unique syn- vs anft-diastereoselectivity in this reaction. In addition,... [Pg.1996]

In 2002, Itoh and Kanemasa found that the combined use of both amine and chiral Lewis acid (R,R)-DBFOX-Ph complex of Ni(II) can be an active catalyst for enantioselective Michael addition of nitromethane or malononitrile to unsaturated carbonyl compounds [37a,b]. Recently, they have reported a new enol ketone synthesis through the reactions between cyclic 1,3-dicarbonyl donors and a,p-unsaturated carbonyl acceptors under the double catalytic activation conditions (10mol% each) of Ni(11)-perchlorate hexahydrate and (2,2,6,6-tetramethylpiperidine (TMP) (114))(Scheme 16.33) [38a,b]. Thus, 1,3-cyclohexanedione (112) is allowed to react with 4-bromo-l-crotonoyl-3,5-dimethylpyrazole (113), in THF at room temperature in the presence of both catalytic amounts to give 4,7,7-trimethyl-3,4,5,6,7,8-hexahy-drobenzopyran-2(H),5-diones (115) in good yields along with high enantioselectivity up to 99% ee. [Pg.352]

Enantioselective Michael addition catalyzed by chiral aluminum Lewis acid is one of the most important methods to obtain enantiomerically pure compounds. As an early work in this fleld, in 1986, Shibasaki and coworkers reported catalytic enantioselective Michael addition of malonates to cyclic enones catalyzed by Li-Al bimetallic catalyst (72) (ALB) derived by premixing LiAlH4 and 2 equivalent of (R)-BINOL in THF (Scheme 6.86) [106, 107]. The structure of (R)-ALB was confirmed by X-ray crystallographic analysis of ALB-cyclohexenone complex. One notable advantage of ALB catalyst is that it works nicely in the tandem Michael-aldol sequence. [Pg.287]

Ferrocen-l,l -diylbismetallacycles are conceptually attractive for the development of bimetal-catalyzed processes for one particular reason the distance between the reactive centers in a coordinated electrophile and a coordinated nucleophile is self-adjustable for specific tasks, because the activation energy for Cp ligand rotation is very low. In 2008, Peters and Jautze reported the application of the bis-palladacycle complex 56a to the enantioselective conjugate addition of a-cyanoacetates to enones (Fig. 31) [74—76] based on the idea that a soft bimetallic complex capable of simultaneously activating both Michael donor and acceptor would not only lead to superior catalytic activity, but also to an enhanced level of stereocontrol due to a highly organized transition state [77]. An a-cyanoacetate should be activated by enolization promoted by coordination of the nitrile moiety to one Pd(II)-center, while the enone should be activated as an electrophile by coordination of the olefinic double bond to the carbophilic Lewis acid [78],... [Pg.159]

Silylketene acetals and enolsilanes can also undergo conjugate addition to a,/ -unsaturated carbonyl derivatives. This reaction is referred to as the Mukaiyama-Michael addition and can also be used as a mild and versatile method for C-C bond formation. As shown in Scheme 8-34, in the presence of C2-symmetric Cu(II) Lewis acid 94, asymmetric conjugate addition proceeds readily, giving product with high yield and enantioselectivity.75... [Pg.478]

This chapter will begin with a discussion of the role of chiral copper(I) and (II) complexes in group-transfer processes with an emphasis on alkene cyclo-propanation and aziridination. This discussion will be followed by a survey of enantioselective variants of the Kharasch-Sosnovsky reaction, an allylic oxidation process. Section II will review the extensive efforts that have been directed toward the development of enantioselective, Cu(I) catalyzed conjugate addition reactions and related processes. The discussion will finish with a survey of the recent advances that have been achieved by the use of cationic, chiral Cu(II) complexes as chiral Lewis acids for the catalysis of cycloaddition, aldol, Michael, and ene reactions. [Pg.4]

Chiral, Lewis acidic bisoxazoline complexes of Mg(II) have been employed as catalysts in asymmetric Michael addition of O-benzyUiydroxylamine to unsaturated amides, (115) -> (116). The enantioselectivity (67-90% ee) was rationalized by transition state (117). This approach constimtes a promising methodology for the synthesis of jS-amino acids. °... [Pg.438]

In 2006, Xu and Xia et al. revealed the catalytic activity of commercially available D-camphorsulfonic acid (CS A) in the enantioselective Michael-type Friedel-Crafts addition of indoles 29 to chalcones 180 attaining moderate enantiomeric excess (75-96%, 0-37% ee) for the corresponding p-indolyl ketones 181 (Scheme 76) [95], This constitutes the first report on the stereoselectivity of o-CSA-mediated transformations. In the course of their studies, the authors discovered a synergistic effect between the ionic liquid BmimBr (l-butyl-3-methyl-l/f-imidazohum bromide) and d-CSA. For a range of indoles 29 and chalcone derivatives 180, the preformed BmimBr-CSA complex (24 mol%) gave improved asymmetric induction compared to d-CSA (5 mol%) alone, along with similar or slightly better yields of P-indolyl ketones 181 (74-96%, 13-58% ee). The authors attribute the beneficial effect of the BmimBr-D-CSA combination to the catalytic Lewis acid activation of Brpnsted acids (LBA). Notably, the direct addition of BmimBr to the reaction mixture of indole, chalcone, d-CSA in acetonitrile did not influence the catalytic efficiency. [Pg.453]

Williams group observed low enantioselectivities for the Michael addition of a prochiral nucleophile, ethyl 2-cyanopropionate 623, to methyl vinyl ketone 624 catalyzed by chiral platinum complexes (Scheme 8.196)." The NMR analysis indicated that these cationic Pt complexes act as Lewis acids toward nitriles. The X-ray crystal structure as well NMR analysis showed that the solvent ligand that is readily displaced by an organic substrate is situated cis to the nitrogen donor in the Pt complex and, therefore, is in a chiral pocket created by the oxazoline ring. [Pg.504]

Other nucleophiles such as nitromethane can also be used for this reaction. Thus, by the catalysis of (fl)-LPB (LaK3tris((/ )-binaphthoxide) (20 mol %), in which La works as a Lewis acid and K-naphthoxide works as a Brpnsted base, nitromethane reacted with chalcone to give the Michael adduct in 85% yield and 93% ee (Scheme 8D.8) [22], Addition of BuOH (120 mol %) gave a beneficial effect on the reactivity as well as the enantioselectivity of this reaction. [Pg.579]

An efficient asymmetric synthesis of the 3-substituted /3-sultams 163 has been reported. The key step of the synthesis is the Lewis acid-catalyzed aza-Michael addition of the enantiopure hydrazines (A)-l-amino-2-methoxy-methylpyrrolidine (SAMP) or CR,l ,l )-2-amino-3-methoxymethyl-2-azabicyclo[3.3.0]octane (RAMBO) to the alke-nylsulfonyl sulfonates 176. /3-Hydrazino sulfonates were obtained in good yield and excellent enantioselectivity. Cleavage of the sulfonates followed by chlorination resulted in the corresponding sulfonyl chlorides 177. The (A)-3-substituted /3-sultams 163 have been obtained in moderate to good yields and high enantioselectivity over two steps, an acidic N-deprotection followed by in situ cyclization promoted by triethylamine (Scheme 55) <2002TL5109, 2003S1856>. [Pg.756]

Low-valent Ru(II) [150] and Rh(I) complexes catalyze aldol and Michael reactions of 2-nitrilo esters. The sequence is thought to be initiated by nitrile complexation to the transition metal. This Lewis acid-activation is followed by an oxidative addition to give a metal hydride and a nitrile complexed enolate as shown in Sch. 36. Examples including diastereoselective Ru(II) catalyzed reactions [151] and enantioselective Rh(I)-catalyzed reactions [152-154] with the large trans-chelating chiral ligand PhTRAP are shown in Tables 8 and 9. [Pg.626]

In 2008, Ye and coworkers also developed a new type of multifunctional cinch-onidine-based catalyst, such as 119 having an additional primary amine moiety, for the Michael addition of nitroalkane to cydic enones [32], In the presence of an acid cocatalyst, the primary amine moiety of 119 can act as a Lewis base to activate the Michael acceptor via iminium formation. The catalysts 119a and 119b (5 mol%) provided quite excellent enantioselectivity (up to 98% ee) for the Michael addition of nitroalkanes to cyclohexenone (Scheme 9.40). The observed retardation of the reaction rate and the opposite sense of enantioselectivity obtained with the catalyst 119b indicated the importance of the configuration of the cydohexane... [Pg.273]

The compounds thus obtained have been used as starting materials for chiral crown ethers h 3> 15 (see Section 5.2.), having applications as enantioselective catalysts in Michael additions (Sections D.1.5.2.1. and D.1.5.2.4.). 3,3 -Dimethyl- and 3,3 -diphenyl-2,2 -dihydroxy-l,T-binaph-thyls 8 and 3 have been applied as ligands for the synthesis of chiral Lewis acids used as stereoselective catalysts in the Diels Alder reaction (Section D.1.6.1.1.1.3.). [Pg.190]

Phenols have been condensed with alkenoylesters to give chromans by an oxa-Michael addition/electrophilic aromatic addition sequence with magnesium(II)- or copper(II)-bis-oxazoline complexes as chiral Lewis acid catalysts (Scheme 17b) [97]. This reaction may be initiated by an oxa-Michael reaction, followed by a hydroarylation of a carbonyl group. The authors suggest that the initial stereodetermining oxa-Michael addition is followed by a fast diastereoselective aromatic substimtion [97]. A nickel Lewis acid, derived from Ni(hfacac)2 (hfacac = 1,LL5,5,5-hexafluoro-3,5-dioxopentane enolate) and chiral Al-oxide ligands, catalyzes the enantioselective oxa-Michael cyclization of 2-tert-butyloxycarbonyl-2 -hydroxy-chalcones to 3-ferf-butoxycarbonyl flavanones, which can be decarboxylated to flavanons in a separate step (Scheme 17c) [98]. A Lewis acid activation of the unsaturated p-ketoester unit can be assumed. [Pg.140]

Preparation of enantiopure intermediates by the use of oxidation reactions was not limited to the synthesis of AB segment (J )-10. The synthesis of the modified daimomycinone, 9-deacetyl-ll-deoxy-9-hydroxymethyldauno-mycinone 44 by Naruta et al. provides an example of enantioselective epox-idation at the stage of a tetracycHc intermediate (Scheme 8) [56]. TetracycUc quinone 42, with the required stereochemistry of the C-4 and C-9 substituents and a protected phenolic hydroxyl group, was prepared in a tandem Michael-Diels-Alder addition of pentadienyltin with acryoylquinone 40 mediated by Lewis acid [57], followed by demethylation, acetylation, and selective hydrolysis. Sharpless enantioselective epoxidation [58] of 42 yielded epoxide 43 in 80% yield and 96% ee. Further transformations of 43 by known procedures, indicated in Scheme 8, furnished the target anthracyclinone 44 in 36% yield from 42. [Pg.154]


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Enantioselective additions

Lewis acid addition

Lewis additive

Michael additions Lewis acid

Michael enantioselective

Michael enantioselectivity

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