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Phosphoric acids, enantioselection asymmetric

The asymmetric hydrogenation of C=N (Eqn. (23)), in contrast with C=0 and C=C bonds, is much less developed. Hexahydrowoquinoline was used as its phosphoric acid salt. Iridium-ferrocenyl complexes were found to be sati.sfactory. After optimisiation, Meyer et al. (1997) were able to realize an enantioselectivity of 89% ee. [Pg.176]

In 2004, Terada and coworkers reported the first asymmetric phosphoric acid-catalyzed Friedel-Crafts alkylation (Scheme 8). Aldimines 11 reacted with commercially available 2-methoxy furan (20) in the presence of BINOL phosphate (/ )-3q (2 mol%, R = S.S-MeSj-C Hj) to provide access to A-Boc-protected 2-furyl amines 21 in high yields (80-96%) and enantioselectivities (86-97% ee) [19]. [Pg.404]

In conjunction with their Friedel-Crafts alkylation, Terada et al. found phosphoric acid (R)-3m (2 mol%, R = 9-anthryl) bearing a bulky 9-anthryl group to mediate the asymmetric Friedel-Crafts-type reaction of a-diazoester 22a with iV-acylated aldimines 26 (Scheme 10). a-Diazo-P-amino esters 27 were obtained in moderate yields (62-89%) and very good enantioselectivities (91-97% ee) [20],... [Pg.405]

Moreover, phosphoric acid (5)-3r (5 mol%, R = SiPhj) bearing a bulky triphe-nylsilyl group turned out to be a suitable catalyst for the asymmetric Friedel-Crafts alkylation of iV-alkyl pyrroles 31 with M-benzoyl-protected aldimines 32 (Scheme 12) [23]. 2-Pyrrolyl amines 33 were obtained in high yields (66-97%) and moderate to high enantioselectivities (42 to >99% ee). [Pg.406]

Three years after the discovery of the asymmetric BINOL phosphate-catalyzed Mannich reactions of silyl ketene acetals or acetyl acetone, the Gong group extended these transformations to the use of simple ketones as nucleophiles (Scheme 25) [44], Aldehydes 40 reacted with aniline (66) and ketones 67 or 68 in the presence of chiral phosphoric acids (R)-3c, (/ )-14b, or (/ )-14c (0.5-5 mol%, R = Ph, 4-Cl-CgH ) to give P-amino carbonyl compounds 69 or 70 in good yields (42 to >99%), flnfi-diastereoselectivities (3 1-49 1), and enantioselectivities (72-98% ee). [Pg.416]

The Schneider group independently reported an asymmetric vinylogous Mannich reaction (Scheme 27) [47]. Addition of silyl dienolates 73 to A-PMP-protected imines 74 was promoted by phosphoric acid (R)-3g (5 mol%, R = Mes) with mesityl substituents to afford tra i -a,p-nnsatnrated 8-amino esters 75 in high yields (66-94%) together with good enantioselectivities (80-92% ee). [Pg.417]

In 2006, Akiyama and coworkers established an asymmetric Brpnsted acid-catalyzed aza-Diels-Alder reaction (Scheme 36) [59]. Chiral BINOL phosphate (R)-3o (5 mol%, R = 2,4,6- Pr3-CgH2) bearing 2,4,6-triisopropylphenyl groups mediated the cycloaddition of aldimines 94 derived from 2-amino-4-methylphenol with Danishefsky s diene 95 in the presence of 1.2 equivalents of acetic acid. Piperidinones 96 were obtained in good yields (72 to >99%) and enantioselectivi-ties (76-91% ee). While the addition of acetic acid (pK= 4.8) improved both the reactivity and the selectivity, the use of benzenesulfonic acid (pK= -6.5) as an additive increased the yield, but decreased the enantioselectivity. A strong achiral Brpnsted acid apparently competes with chiral phosphoric acid 3o for the activation of imine 94 and catalyzes a nonasymmetric hetero-Diels-Alder reaction. The role of acetic acid remains unclear. [Pg.424]

Prior to this work, Renaud and coworkers described an alternative phosphoric acid-catalyzed approach to DHPs 113 commencing with p-enaminoesters such as 114 and cinnamaldehydes 111. Besides developing a catalytic nonasymmetric protocol, the authors attempted a BINOL phosphate (5)-3k-catalyzed (R = 1-naphthyl) asymmetric version attaining moderate enantioselectivity (50% ee) (Scheme 45) [70]. [Pg.431]

Akiyama and coworkers extended the scope of electrophiles applicable to asymmetric Brpnsted acid catalysis with chiral phosphoric acids to nitroalkenes (Scheme 57). The Friedel-Crafts alkylation of indoles 29 with aromatic and aliphatic nitroalkenes 142 in the presence of BINOL phosphate (7 )-3r (10 mol%, R = SiPhj) and 3-A molecular sieves provided Friedel-Crafts adducts 143 in high yields and enantioselectivities (57 to >99%, 88-94% ee) [81]. The use of molecular sieves turned out to be critical and significantly improved both the yields and enantioselectivities. [Pg.440]

In 2008, the Ackennann group reported on the use of phosphoric acid 3r (10 mol%, R = SiPhj) as a Brpnsted acid catalyst in the unprecedented intramolecular hydroaminations of unfunctionaUzed alkenes alike 144 (Scheme 58) [82], BINOL-derived phosphoric acids with bulky substituents at the 3,3 -positions showed improved catalytic activity compared to less sterically hindered representatives. Remarkably, this is the first example of the activation of simple alkenes by a Brpnsted acid. However, the reaction is limited to geminally disubstituted precursors 144. Their cyclization might be favored due to a Thorpe-Ingold effect. An asymmetric version was attempted by means of chiral BINOL phosphate (R)-3( (20 mol%, R = 3,5-(CF3)2-CgH3), albeit with low enantioselectivity (17% ee). [Pg.441]

Chiral phosphoric acids mediate the enantioselective formation of C-C, C-H, C-0, C-N, and C-P bonds. A variety of 1,2-additions and cycloadditions to imines have been reported. Furthermore, the concept of the electrophilic activation of imines by means of phosphates has been extended to other compounds, though only a few examples are known. The scope of phosphoric acid catalysis is broad, but limited to reactive substrates. In contrast, chiral A-triflyl phosphoramides are more acidic and were designed to activate less reactive substrates. Asymmetric formations of C-C, C-H, C-0, as well as C-N bonds have been established. a,P-Unsaturated carbonyl compounds undergo 1,4-additions or cycloadditions in the presence of A-triflyl phosphoramides. Moreover, isolated examples of other substrates can be electrophil-ically activated for a nucleophilic attack. Chiral dicarboxylic acids have also found utility as specific acid catalysts of selected asymmetric transformations. [Pg.454]

An enantioselective Strecker reaction involving Brpnsted acid catalysis uses a BINOL-phosphoric acid, which affords ees up to 93% in hydrocyanations of aromatic aldimines in toluene at -40 °C.67 The asymmetric induction processes in the stereoselective synthesis of both optically active cis- and trans-l-amino-2-hydroxycyclohexane-l -carboxylic acids via a Strecker reaction have been investigated.68 A 2-pyridylsulfonyl group has been used as a novel stereocontroller in a Strecker-type process ees up to 94% are suggested to arise from the ability of a chiral Lewis acid to coordinate to one of the sulfonyl (g)... [Pg.10]

Phosphoric acid catalysts, bearing bulky groups, have been devised for the asymmetric transfer hydrogenation of imines with Hantsch ester. With the catalyst (14), (g) enantioselectivity up to 93% has been achieved in the reduction of aromatic imines. [Pg.122]

Another important means of mediation of metal-free catalytic enantioselective Mannich-type reactions is via electrophilic activation of the preformed imines by chiral Bronstedt acids [7, 8, 46], By using this strategy Terada and coworkers performed chiral phosphoric acid-catalyzed direct asymmetric Mannich-type reactions between Boc-protected imines and acetoacetone that furnished aryl /3-amino... [Pg.370]

Kadyrov R, Riermeier TH (2003) Highly enantioselective hydrogen-transfer reductive amination catalytic asymmetric synthesis of primary amines. Angew Chem Int Ed Engl 42 5472-5474 Kang Q, Zhao ZA, You SL (2007) Highly enantioselective Friedel-Crafts reaction of indoles with imines by a chiral phosphoric acid. J Am Chem Soc 129 1484-1485... [Pg.248]

The TBS group was chosen as silyl fragment within the dienolate to prevent a attack of the imines on the nucleophile. As chiral catalyst we employed a BINOL based phosphoric acid of the same type that Akiyama and Terada had established in asymmetric catalysis and found 3,3 mesityl groups optimal for the enantioselectivity of the reaction. The reactions were run at 30 °C in a solvent mixture of fBuOH, 2 methyl 2 butanol,andTHFin equal amounts containing anadditionallequivofwater. [Pg.166]

The enamine catalysis detailed above proceeds via activation of the Mannich donor. An alternate strategy to the catalysis of the Mannich reaction is by the use of Brensted acids that activate the acceptor imine by protonation on nitrogen. Some of the most successful asymmetric variants of this process use BINOL-based phosphoric acids as catalysts. For instance Terada and coworkers used (7.144) to effect highly enantioselective addition of acetylacetone to a range of aryl aldimines ... [Pg.199]

Akiyama and Zhu have described the first example of use of the phosphoric acid (127) as an efficient reducing agent for the enantioselective, asymmetric transfer hydrogenation reaction of imines (171). The synthesized amines (172) were obtained in excellent enantioselectivities (Scheme 46). [Pg.240]

The first, asymmetric, three-component [4 + 2] cycloaddition reaction of cinnamaldehydes (179), primary amines (180), and azalactones (178) by using the phosphoric acid derivative (123) as the catalyst, which yielded 3-amino-3,4-dihydropyridinones (181) in high enantioselectivity (up to 96%), has been disclosed by Gong et al. (Scheme 49). The use of this reaction in the synthesis of benzo[<2]quinolizidine derivatives of high optical purity has been also described. [Pg.241]

The asymmetric hydrophosphonylation reaction of aldimines (207) with dialkyl phosphites (206) has been reported using catalytical amounts of the phosphoric acid (125), derived from (7 )-BINOL to afford (l )-amino phos-phonates (208) in good to high enantioselectivities (up to 90% cc) (Scheme 58). ... [Pg.244]


See other pages where Phosphoric acids, enantioselection asymmetric is mentioned: [Pg.23]    [Pg.1310]    [Pg.406]    [Pg.1310]    [Pg.332]    [Pg.411]    [Pg.415]    [Pg.432]    [Pg.433]    [Pg.224]    [Pg.230]    [Pg.250]    [Pg.131]    [Pg.17]    [Pg.139]    [Pg.76]    [Pg.93]    [Pg.113]    [Pg.115]    [Pg.123]    [Pg.71]    [Pg.417]    [Pg.56]    [Pg.66]    [Pg.78]    [Pg.276]    [Pg.54]    [Pg.81]   


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Asymmetric enantioselectivity

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