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Enantioselectivity nucleophilic reactions

In the present study the dimer (salen)CoAlX3 showed enhanced activity and enantioselectivity. The catalyst can be synthesized easily by readily commercially available precatalyst Co(salen) in both enantiomeric forms. Potentially, the catalyst may be used on an industrial scale and could be recycled. Currently we are looking for the applicability of the catalyst to asymmetric reaction of terminal and meso epoxides with other nucleophiles and related electrophile-nucleophile reactions. [Pg.208]

Chapter 2 provided a general introduction to the a-alkylation of carbonyl compounds, as well as the enantioselective nucleophilic addition on carbonyl compounds. Chiral auxiliary aided a-alkylation of a carbonyl group can provide high enantioselectivity for most substrates, and the hydrazone method can provide routes to a large variety of a-substituted carbonyl compounds. While a-alkylation of carbonyl compounds involves the reaction of an enolate, the well known aldol reaction also involves enolates. [Pg.135]

Increasing interest is expressed in diastereoselective addition of organometallic reagents to the ON bond of chiral imines or their derivatives, as well as chiral catalyst-facilitated enantioselective addition of nucleophiles to pro-chiral imines.98 The imines frequently selected for investigation include N-masked imines such as oxime ethers, sulfenimines, and /V-trimcthylsilylimines (150-153). A variety of chiral modifiers, including chiral boron compounds, chiral diols, chiral hydroxy acids, A-sull onyl amino acids, and /V-sulfonyl amido alcohols 141-149, have been evaluated for their efficiency in enantioselective allylboration reactions.680... [Pg.180]

Fluorine-containing compounds can also be synthesized via enantioselective Reformatsky reaction using bromo-difluoroacetate as the nucleophile and chiral amino alcohol as the chiral-inducing agent.86 As shown in Scheme 8-41, 1 equivalent of benzaldehyde is treated with 3 equivalents of 111 in the presence of 2 equivalents of 113, providing a,a-difluoro-/ -hydroxy ester 112 at 61% yield with 84% ee. Poor results are observed for aliphatic aldehyde substrates. For example, product 116 is obtained in only 46% ee. [Pg.483]

The ammonium catalyst can also influence the reaction path and higher yields of the desired product may result, as the side reactions are eliminated. In some cases, the structure of the quaternary ammonium cation may control the product ratio with potentially tautomeric systems as, for example, with the alkylation of 2-naph-thol under basic conditions. The use of tetramethylammonium bromide leads to predominant C-alkylation at the 1-position, as a result of the strong ion-pair binding of the hard quaternary ammonium cation with the hard oxy anion, whereas with the more bulky tetra-n-butylammonium bromide O-alkylation occurs, as the binding between the cation and the oxygen centre is weaker [11], Similar effects have been observed in the alkylation of methylene ketones [e.g. 12, 13]. The stereochemistry of the Darzen s reaction and of the base-initiated formation of cyclopropanes under two-phase conditions is influenced by the presence or absence of quaternary ammonium salts [e.g. 14], whereas chiral quaternary ammonium salts are capable of influencing the enantioselectivity of several nucleophilic reactions (Chapter 12). [Pg.2]

This chemistry was extended to a catalytic enantioselective alkenylation and phenylation of aldehydes and a-ketoesters. Using CuF-DTBM-SEGPHOS complex, products were obtained with excellent enantioselectivity from a wide range of aldehydes including aromatic and aliphatic aldehdyes, [Eq. (13.26)]. Previously catalytic enantioselective vinylation and phenylation are restricted using the corresponding zinc reagents. The active nucleophile is proposed to be an alkenyl or phenyl copper, based on NMR studies. The chiral CuF catalyst can also be applied to a catalytic enantioselective aldol reaction to ketones... [Pg.397]

In 2005, Rovis and Reynolds reported the synthesis of a-chloroesters from a,a-dichloroaldehydes using chiral, enantioenriched not chirald pre-catalyst 75c [115], As shown in Table 14, the reaction scope includes a variety of dichloroaldehydes 201 that afford desired esters 202 in good yields and enantioselectivities. The reaction is compatible with various phenols, including electron-rich and electron-poor nucleophiles. Standard reaction conditions accommodate a variety of aldehydes, although substrates containing P-branching inhibit reactivity. [Pg.114]

In 1997, the first truly catalytic enantioselective Mannich reactions of imines with silicon enolates using a novel zirconium catalyst was reported [9, 10]. To solve the above problems, various metal salts were first screened in achiral reactions of imines with silylated nucleophiles, and then, a chiral Lewis acid based on Zr(IV) was designed. On the other hand, as for the problem of the conformation of the imine-Lewis acid complex, utilization of a bidentate chelation was planned imines prepared from 2-aminophenol were used [(Eq. (1)]. This moiety was readily removed after reactions under oxidative conditions. Imines derived from heterocyclic aldehydes worked well in this reaction, and good to high yields and enantiomeric excesses were attained. As for aliphatic aldehydes, similarly high levels of enantiomeric excesses were also obtained by using the imines prepared from the aldehydes and 2-amino-3-methylphenol. The present Mannich reactions were applied to the synthesis of chiral (3-amino alcohols from a-alkoxy enolates and imines [11], and anti-cc-methyl-p-amino acid derivatives from propionate enolates and imines [12] via diastereo- and enantioselective processes [(Eq. (2)]. Moreover, this catalyst system can be utilized in Mannich reactions using hydrazone derivatives [13] [(Eq. (3)] as well as the aza-Diels-Alder reaction [14-16], Strecker reaction [17-19], allylation of imines [20], etc. [Pg.144]

Fu and co-workers have also applied their planar chiral catalyst 9 to dynamic kinetic resolution of racemic azalactones [50], Azalactones 54 racemize under the reaction conditions, allowing all material to be funneled to optically pure product. Protected (S)-amino acids 55 are formed in excellent yields with moderate enantioselectivities (83-98% yield, 44-61% ee, see Scheme 11). Use of more sterically encumbered alcohols as nucleophiles increases enantioselectivities but reaction rates become slower. [Pg.201]

Enantiomeric purity, palladacycle applications, 8, 295 Enantioselective addition reactions, nucleophiles to allylic... [Pg.102]

In one of the earliest reports on enantioselective radical reactions, chiral Lewis acid mediated conjugate addition followed by enantioselective H-atom transfer a to a carbonyl was reported by Sato and co-workers (Scheme 3) [22], The single point binding chiral aluminum complex presumably coordinates to the carbonyl oxygen of the lactone as shown in 10. The strong Lewis acidity of the aluminum complex activates the substrate 7 to nucleophilic conjugate addition, which is followed by an enantioselective H-atom transfer from BuaSnH in a chiral environment provided by BINOL ligand in 8. Only 28% ee was observed for product 9. [Pg.110]

Related enantioselective protonation reactions based on the use of thiophenol as a nucleophile have also been reported by Kumar et al. these reactions led to enantioselectivity of 45-51% ee [9]. For example in the presence of 20 mol% quinine 11 the adduct 10 was synthesized in 85% yield and with 46% ee (Scheme 9.3, Eq. b). Reaction product 10 has subsequently been used as an intermediate in the synthesis of (S)-naproxen, 12, which was obtained in 85% ee (after recrystallization). [Pg.271]

Nevertheless, the use of chirally modified Lewis acids as catalysts for enantioselective aminoalkylation reactions proved to be an extraordinary fertile research area [3b-d, 16]. Meanwhile, numerous publications demonstrate their exceptional potential for the activation and chiral modification of Mannich reagents (generally imino compounds). In this way, not only HCN or its synthetic equivalents but also various other nucleophiles could be ami-noalkylated asymmetrically (e.g., trimethylsilyl enol ethers derived from esters or ketones, alkenes, allyltributylstannane, allyltrimethylsilanes, and ketones). This way efficient routes for the enantioselective synthesis of a variety of valuable synthetic building blocks were created (e.g., a-amino nitriles, a- or //-amino acid derivatives, homoallylic amines or //-amino ketones) [3b-d]. [Pg.136]

Basically, two different routes are conceivable for their asymmetric construction 1) nucleophilic substitution reaction with a fluoride anion and 2) electrophilic addition of fluoronium cations to activated or masked carbanions. First attempts on enantioselective nucleophilic fluorination date back to the pioneering work of Hann and Sampson [3]. In an ambitious dehydroxylation/fluorination sequence the authors reacted a racemic a-trimethylsiloxy ester with a half molar equivalent of an enantiomerically pure proline-derived aminofluorosulphurane in hope to achieve a kinetic resolution. Unfortunately, the fluorinated product was obtained without significant enantiomeric excess. [Pg.201]

Enders D, Balensiefer T, Niemeier O, Christmann M (2007c) Nucleophilic N-heterocyclic carbenes om asymmetric organocatalysis. In Dalko PI (ed) Enantioselective organocatalysis—reactions and experimental procedures. Wiley-VCII, Weinheim, p 331... [Pg.114]

Chromatography) (equation 82). These complexes are used as enantioselective nucleophilic catalysts for reactions such as the rearrangements of O-acylated azlactones, oxindoles, and benzofuranones, and the kinetic resolution of secondary alcohols via acylation. X-ray crystal structures have been obtained for iV-acylated derivatives of (366), allowing for characterization of a likely intermediate along the catalytic pathway. [Pg.2077]

The enantioselective nucleophilic addition of prochiral C=0 and C=N moieties to the corresponding saturated chiral products is one of the most important stereoselective transformations on both the laboratory and the industrial scale. Although, over the past few decades, remarkable scientific achievements have been made in these research areas by using a variety of transitional metal-based catalysts, the sensitivity of the reaction to moisture and oxygen, as well as the toxic metal contamination of the product, usually restrict its practical application. Thus, currently, there is much interest in chiral organocatalysts, as they tend to be less toxic and more environmental friendly than traditional metal-based catalysts [1]. They are usually robust and thus tolerate moisture and oxygen, so that they usually do not demand any special reaction conditions. [Pg.197]

In 1994, the first enantioselective trifluoromethylation reaction was achieved with the Ruppert-Prakash reagent, TMSCF3, in the presence of the cinchona-based quaternary ammonium fluoride 140 [65]. The chiral induction can arise from the dual activation mode of the catalyst, that is, the fluoride anion acts as the nucleophilic activator of (TMS)CF3 and the chiral ammonium cation activates the carbonyl group of 141. However, the observed ee values of the obtained carbinols 142 do not exceed 51 % and decrease considerably when nonaromatic carbonyl compounds (15% ee for R1 = n-C7H15 R2 = H) are used, which implies that 7t-7t stacking interactions between the carbonyl compound and cinchoninium occur (Scheme 8.54). [Pg.234]

Cinchona-catalyzed enantioselective nucleophilic 1,2-addition reactions... [Pg.484]

A variety of nucleophiles can be added in a conjugate manner to a,p-unsaturated ketones. The reaction is reversible, so the main difficulty is finding conditions that drive the equilibrium to the right. For catalytic enantioselective Michael reactions, see Krause, N. Hoffinann-Roder, A. Synthesis 2001,171-196. For intramolecular Michael reactions see Little, R.D. Masjedizadeh, M. R. Wallquist, O. Mcloughlin, J. 1. Org. React. 1995, 47, 315-552. [Pg.60]

Scheme 11.13 Regioselective and enantioselective nucleophilic aromatic substitution reactions. Scheme 11.13 Regioselective and enantioselective nucleophilic aromatic substitution reactions.
Jorgensen developed a catalytic regioselective and enantioselective nucleophilic aromatic substitution reaction of activated aromatic compounds with 1,3-dicarbonyl compounds under phase-transfer conditions. This was crucial for obtaining the C-arylated product 61 predominantly with high enantioselectivity by replacing a benzyl with a benzoate group in the cinchona alkaloids-derived phase-transfer catalyst (Scheme 11.13) [49]. [Pg.397]


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Enantioselective reaction

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