Asymmetric Ion‐Pairing Catalysis

Brak, Katrien; Jacobsen, Eric N.

doi:10.1002/anie.201205449

Cited by 938 publications

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“…Kobayashi et al have reported the first anionic phase-transfer reaction using tetrakis(3,5-bis(trifluoromethyl) phenyl) borate (TFPB) anion. [4][5][6] Recently, asymmetric anionic phase-transfer reactions 7,8) have been reported using chiral phosphates with an aziridinium cation 9) and N-haloammonium cations. [10][11][12][13][14][15][16][17][18] …”

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Acceleration of Acid-Catalyzed Hydrolysis in a Biphasic System by Sodium Tetracyanocyclopentadienides

Sakai

Bito

Itakura

et al. 2016

CHEMICAL & PHARMACEUTICAL BULLETIN

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The hydrolysis of tert-butyldimethylsilyl L-menthyl ether (3) in a CH 2 Cl 2 -1 M HCl biphasic solvent system was accelerated by the addition of sodium tetracyanocyclopentadienides 1. Particularly, the reaction rate was enhanced using sodium salt 1a-c with a lipophilic substituent on the cyclopentadienide ring. From the results obtained by a triphasic experiment, hydrolysis proceeds via the formation of hydronium ion 2 in the aqueous phase by ion exchange, followed by the transfer of 2 to the CH 2 Cl 2 phase.Key words phase-transfer reaction; hydrolysis; tetracyanocyclopentadienide; acid-catalyzed reaction Phase-transfer reactions have garnered increasing attention in organic chemistry because of their mild, sustainable conditions. 1) Phase-transfer catalysts (PTCs) enhance the reactivity of anionic reagents by forming a lipophilic ion pair, mediating a reaction in the organic phase or at the interface between two phases. Enantioselective phase-transfer reactions catalyzed by chiral quaternary ammonium salts are one of the representative methods for synthesizing optically active molecules.2,3) Anionic PTCs have also been developed for reactions where lipophilic anions enhance the solubility of the reactive cationic species, thereby promoting the reactions. Kobayashi et al. have reported the first anionic phase-transfer reaction using tetrakis(3,5-bis(trifluoromethyl) phenyl) borate (TFPB) anion. [4][5][6] Recently, asymmetric anionic phase-transfer reactions 7,8) have been reported using chiral phosphates with an aziridinium cation 9) and N-haloammonium cations. [10][11][12][13][14][15][16][17][18]

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Acceleration of Acid-Catalyzed Hydrolysis in a Biphasic System by Sodium Tetracyanocyclopentadienides

Sakai

Bito

Itakura

et al. 2016

CHEMICAL & PHARMACEUTICAL BULLETIN

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“…1) rather than through formation of covalent adducts or lowest unoccupied molecular orbital-lowering protonation (or hydrogen bonding), which has generally required substrates containing carbonyl or imine moieties (11)(12)(13). This generalization applies to chiral phosphoric acids, which have been predominantly used in activation of the electrophile, although hydrogen bonding to the nucleophile has also been implicated as a key component (14).…”

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“…This generalization applies to chiral phosphoric acids, which have been predominantly used in activation of the electrophile, although hydrogen bonding to the nucleophile has also been implicated as a key component (14). More recently the anionic conjugate bases of chiral phosphoric acids (i.e., chiral phosphate anions) have received attention as counterions for positively charged electrophilic intermediates, wherein ion pairing with the phosphate anion provides a suitable chiral environment for subsequent enantioselective transformations of the electrophilic species (11)(12)(13). The generality of the concept of ion pair catalysis has allowed the application of these highly tunable scaffolds to a diverse range of transformations in which carbonyl or imine activation is clearly inapplicable (15)(16)(17).…”

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“…The generality of the concept of ion pair catalysis has allowed the application of these highly tunable scaffolds to a diverse range of transformations in which carbonyl or imine activation is clearly inapplicable (15)(16)(17). As part of both aforementioned modes of reactivity, hydrogen bonds between chiral phosphoric acids or phosphate anions and reacting functionality are often invoked as crucial interactions for achieving high levels of enantioselectivity (11)(12)(13)(14). We speculated that hydrogen-bonding interactions with substrate functionality may play a key role, via transition state organization, even when the interacting functionality does not directly participate in the transformation.…”

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A combination of directing groups and chiral anion phase-transfer catalysis for enantioselective fluorination of alkenes

Wang

Drljevic

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

115

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We report a catalytic enantioselective electrophilic fluorination of alkenes to form tertiary and quaternary C(sp3)-F bonds and generate β-amino-and β-aryl-allylic fluorides. The reaction takes advantage of the ability of chiral phosphate anions to serve as solid-liquid phase transfer catalysts and hydrogen bond with directing groups on the substrate. A variety of heterocyclic, carbocyclic, and acyclic alkenes react with good to excellent yields and high enantioselectivities. Further, we demonstrate a one-pot, tandem dihalogenation-cyclization reaction, using the same catalytic system twice in series, with an analogous electrophilic brominating reagent in the second step.asymmetric | organocatalysis | hydrogen-bonding

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“…The initial S N 2 addition of an appropriate solvent, such as etheric solvent, and/or additive 15) to α-donor 1 would form a β-linked intermediate A, to which the following S N 2 attacked by an employed amide would afford the desired α-linked product. As in our previous report, 8) we have chosen an XB-donor/thiourea co-catalytic system for the activation of the leaving group (LG) of 1, mainly due to the following reasons: 1) XB interaction would be effective in relatively polar etheric solvent, and 2) tuning of both HB donor and XB donor would improve their ability to trap the LG via anion binding, 16) preventing the undesired rearrangement of the LG.…”

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Organocatalytic Direct α-Selective <i>N</i>-Glycosylation of Amide with Glycosyl Trichloroacetimidate

Kobayashi

Takemoto

2018

Chem. Pharm. Bull.

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Through the synergistic catalytic effect of the halogen bond (XB) donor and thiourea catalyst, a direct α-selective N-glycosylation of the amide residue of asparagine derivative was achieved using readily accessible glycosyl trichloroacetimidate. n-Butyl methyl ether was found to be the most suitable solvent for the α-selectivity.Key words glycosylation; organocatalyst; halogen bond; hydrogen bond; green chemistry N-Glycosides are found in a variety of bioactive compounds, including natural products. 1) Sugar moieties are known to extend the diversity of molecules, altering their property, structure, and biological activities. 2) However, synthetic methods for N-glycosides have not been well developed, [3][4][5][6][7][8] as compared with the preparation of O-glycosides. In particular, stereoselective synthesis of α-N-glycosides is one of the most challenging issues despite their potentials as therapeutic compounds. [9][10][11] In 2003, DeShong's group has reported a highly α-selective synthesis of N-glycosides through a Cu-mediated acylation of glycopyranosyl isoxazoline intermediates generated from the corresponding azides, 5) while anomerization of 1-aminoglycopyranosyl derivatives is generally a significant problem. 4) Direct N-glycosylation of amides has emerged as an alternative approaches, 6-8) but those reports relied on the neighboring group participation to give β-N-glycosides (Chart 1a).Herein, we report the first direct α-N-glycosylation of amide with glycosyl trichloroacetimidate 12) using halogen bond (XB) donor 13) /Schreiner thiourea 14) co-catalytic system. We envisioned that α-selectivity would be achieved through the double inversion strategy (Chart 1b). The initial S N 2 addition of an appropriate solvent, such as etheric solvent, and/or additive 15) to α-donor 1 would form a β-linked intermediate A, to which the following S N 2 attacked by an employed amide would afford the desired α-linked product. As in our previous report, 8) we have chosen an XB-donor/thiourea co-catalytic system for the activation of the leaving group (LG) of 1, mainly due to the following reasons: 1) XB interaction would be effective in relatively polar etheric solvent, and 2) tuning of both HB donor and XB donor would improve their ability to trap the LG via anion binding, 16) preventing the undesired rearrangement of the LG.We first screened the reaction conditions for the direct α-N-glycosylation of asparagine derivative 3 with glycosyl donor 1 (Table 1). According to our previous work, 2-iodoimidazolium salt (XB1) 13) was examined in conjunction with HB1 in dichloromethane. 8) As we expected, the combination of HB1 and XB1 was essential for the production of desired N-glycoside 2a (entries 1-3), although almost no α/β selectivity was observed (entry 3). A control experiment with non-halogenated azolium 5 did not furnish 2a at all (entry 4), indicating that XB interaction would play an important role. The chemical yields were slightly improved using XB2 and XB3 (entries 5 and 6), whereas the undesired glycosyl trichl...

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Asymmetric Ion‐Pairing Catalysis

Cited by 938 publications

References 231 publications

Acceleration of Acid-Catalyzed Hydrolysis in a Biphasic System by Sodium Tetracyanocyclopentadienides

Acceleration of Acid-Catalyzed Hydrolysis in a Biphasic System by Sodium Tetracyanocyclopentadienides

A combination of directing groups and chiral anion phase-transfer catalysis for enantioselective fluorination of alkenes

Organocatalytic Direct α-Selective <i>N</i>-Glycosylation of Amide with Glycosyl Trichloroacetimidate

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