Enantioselectivity nucleophilic substitution

An intriguing feature is that the previously unknown bisindoles 154 display atropisomerism as a result of the rotation barrier about the bonds to the quaternary carbon center. With the use of A-triflyl phosphoramide (1 )-41 (5 mol%, R = 9-phenanthryl), bisindole 154a could be obtained in 62% ee. Based on their experimental results, the authors invoke a Brpnsted acid-catalyzed enantioselective, nucleophilic substitution following the 1,2-addition to rationalize the formation of the bisindoles 154 (Scheme 65). 

TT-Allylpalladium intermediates described in this section can undergo either a /3-H elimination or a nucleophilic substitution reaction. Enantioselective nucleophilic substitution can afford the corresponding chiral compounds with high enantiomeric excesses. 

Gong and co-workers [80] developed an organocatalytic enantioselective nucleophilic substitution reaction of 3-hydroxyoxindoles with enecarbamates catalyzed by chiral phosphoric acid, which provided a new approach for the preparation of 3,3 -disubstituted oxindoles with a quaternary all-carbon stereogenic center. They demonstrated the efficiency of this methodology in the enantioselective construction of (-h)-folicanthine (198) (Scheme 17.33). Under the optimized reaction conditions, the enantioselective substimtion reaction of 194 with enecarbamate 195 using catalyst 196 afforded 197 in 82% yield and 90% ee. Compound 197 was then transformed into (+)-folicanthine (198) by a 12-step sequence in 3.7% overall yield. 

Scheme 53 Enantioselective nucleophilic substitution in aromatic propargylic alcohols catalyzed by chiral thiolate-bridged diruthenium(III) complexes...

Helquist et al. [129] have reported molecular mechanics calculations to predict the suitability of a number of chiral-substituted phenanthrolines and their corresponding palladium-complexes for use in asymmetric nucleophilic substitutions of allylic acetates. Good correlation was obtained with experimental results, the highest levels of asymmetric induction being predicted and obtained with a readily available 2-(2-bornyl)-phenanthroline ligand (90 in Scheme 50). Kocovsky et al. [130] prepared a series of chiral bipyridines, also derived from monoterpene (namely pinocarvone or myrtenal). They synthesized and characterized corresponding Mo complexes, which were found to be moderately enantioselective in allylic substitution (up to 22%). 

Sulfoximines bearing a chiral sulfur atom have recently emerged as valuable ligands for metal-catalysed asymmetric synthesis.In particular, C2-symmetric bis(sulfoximines), such as those depicted in Scheme 1.51, were applied to the test reaction, achieving enantioselectivities of up to 93% ee. The most selective ligand (R = c-Pent, R = Ph) of the series was also applied to the nucleophilic substitution reaction of l,3-diphenyl-2-propenyl acetate with substituted malonates, such as acetamido-derived diethylmalonate, which provided the corresponding product in 89% yield and 98% ee. 

The ANM group was selected as the nitrogen protecting group for the novel asymmetric nucleophilic substitution providing the optimum enantioselectivity. 

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. 

The formation of chromane derivatives has also been realised in the palladium catalyzed intramolecular nucleophilic substitution of allyl carbonates (Tsuji-Trost reaction). In most cases the reaction is accompanied by the formation of a new centre of chirality. Using Trost s chiral ligand the ring closure was carried out in an enantioselective manner. The asymmetric allylation of the phenol derivative shown in 4.20. was achieved both in good yield and with excellent selectivity.23... 

Enantioselective catalytic alkylation is a versatile method for construction of stereo-genic carbon centers. Typically, phase-transfer catalysts are used and form a chiral ion pair of type 4 as an key intermediate. In a first step, an anion, 2, is formed via deprotonation with an achiral base this is followed by extraction in the organic phase via formation of a salt complex of type 4 with the phase-transfer organocata-lyst, 3. Subsequently, a nucleophilic substitution reaction furnishes the optically active alkylated products of type 6, with recovery of the catalyst 3. An overview of this reaction concept is given in Scheme 3.1 [1],... 

An important issue is the right choice of substrate 1 which functions as an anion precursor. Successful organocatalytic conversions have been reported with indanones and benzophenone imines of glycine derivatives. The latter compounds are, in particular, useful for the synthesis of optically active a-amino acids. Excellent enantioselectivity has been reported for these conversions. In the following text the main achievements in this field of asymmetric organocatalytic nucleophilic substitutions are summarized [1, 2], The related addition of the anions 2 to Michael-acceptors is covered by chapter 4. 

Aldol reactions using a quaternary chinchona alkaloid-based ammonium salt as orga-nocatalyst Several quaternary ammonium salts derived from cinchona alkaloids have proven to be excellent organocatalysts for asymmetric nucleophilic substitutions, Michael reactions and other syntheses. As described in more detail in, e.g., Chapters 3 and 4, those salts act as chiral phase-transfer catalysts. It is, therefore, not surprising that catalysts of type 31 have been also applied in the asymmetric aldol reaction [65, 66], The aldol reactions were performed with the aromatic enolate 30a and benzaldehyde in the presence of ammonium fluoride salts derived from cinchonidine and cinchonine, respectively, as a phase-transfer catalyst (10 mol%). For example, in the presence of the cinchonine-derived catalyst 31 the desired product (S)-32a was formed in 65% yield (Scheme 6.16). The enantioselectivity, however, was low (39% ee) [65],... 

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. 

Chung et al. reported the enantioselective synthesis of chiral NHCs, such as 6, using a chiral ferrocene derivative (Scheme 8) [28]. The nucleophilic substitution of the hydroxy function by an imidazole in an acidic medium gives the imidazolium salt with retention of the configuration at the chiral C-atom. 

The catalytic activation of allylic carbonates for the alkylation of soft car-bonucleophiles was first carried out with ruthenium hydride catalysts such as RuH2(PPh3)4 [108] and Ru(COD)(COT) [109]. The efficiency of the cyclopen-tadienyl ruthenium complexes CpRu(COD)Cl [110] and Cp Ru(amidinate) [111] was recently shown. An important catalyst, [Ru(MeCN)3Cp ]PF6, was revealed to favor the nucleophilic substitution of optically active allycarbonates at the most substituted allyl carbon atom and the reaction took place with retention of configuration [112] (Eq. 85). The introduction of an optically pure chelating cyclopentadienylphosphine ligand with planar chirality leads to the creation of the new C-C bond with very high enantioselectivity from symmetrical carbonates and sodiomalonates [113]. 

Terminal epoxides of high enantiopurity are among the most important chiral building blocks in enantioselective synthesis, because they are easily opened through nucleophilic substitution reactions. Furthermore, this procedure can be scaled to industrial levels with low catalyst loading. Chiral metal salen complexes have also been successfully applied to the asymmetric hydroxylation of C H bonds, asymmetric oxidation of sulfides, asymmetric aziridination of alkenes, and the asymmetric alkylation of keto esters to name a few. 

Soai et al. [62a] first reported the use of sihca gel or alumina as a heterogeneous support for chiral catalysts in the enantioselective addition of dialkylzincs to aldehydes. Chiral N-alkyhrorephedrines (R = Me, Et, n-Pr) were immobilized covalently on (3-chloropropyl)silyl-functionalized alumina or silica gel via a nucleophilic substitution. However, the catalytic activities and enantioselectivities were only moderate (24—59% ee) in comparison with those of homogeneous and polymer-... 

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]. 

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