Phosphates BINOL

Recently, it has been shown by Hodgson and coworkers [195] that this domino reaction can indeed be performed in an enantioselective manner. Thus, treatment of 6/2-31 using the BINOL-phosphate Rh2-complex 6/2-34 at -15 °C gave (+)-6/2-33, probably via 6/2-32, in 66% yield and 90% ee (Scheme 6/2.6). Several other substrates and chiral catalysts have also been employed, though with lower selectivity. 

Axially chiral phosphoric acid 3 was chosen as a potential catalyst due to its unique characteristics (Fig. 2). (1) The phosphorus atom and its optically active ligand form a seven-membered ring which prevents free rotation around the P-0 bond and therefore fixes the conformation of Brpnsted acid 3. This structural feature cannot be found in analogous carboxylic or sulfonic acids. (2) Phosphate 3 with the appropriate acid ity should activate potential substrates via protonation and hence increase their electrophilicity. Subsequent attack of a nucleophile and related processes could result in the formation of enantioenriched products via steren-chemical communication between the cationic protonated substrate and the chiral phosphate anion. (3) Since the phosphoryl oxygen atom of Brpnsted acid 3 provides an additional Lewis basic site, chiral BINOL phosphate 3 might act as bifunctional catalyst. 

Fig. 2 Br0nsted acidic and basic sites of BINOL phosphates...

Scheme 3 Synthesis of BINOL phosphates according to Akiyama and Terada...

The Akiyama group tested various BINOL phosphates 3 as catalysts for the indirect Mannich reaction of aldimines 8 derived from 2-aminophenol with silyl ketene acetals 9 (Scheme 4). All of these Brpnsted acids furnished P-amino ester 10a in (nearly) quantitative yields. Both the reaction rates (4-46 h) and the enantioselectivities (27-87% ee) were strongly dependent on the nature of the substituents at the 3,3 -positions. 

After having proven that BINOL phosphates serve as organocatalysts for asymmetric Mannich reactions, Akiyama and Terada et al. reasoned that the concept of electrophilic activation of imines by means of chiral phosphoric acids might be applicable to further asymmetric transformations. Other groups recognized the potential of these organocatalysts as well. They showed that various nucleophiles can be used. Subsequently, chiral phosphates were found to activate not only imines, but also other substrates. 

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]. 

Two years after the discovery of the first asymmetric Br0nsted acid-catalyzed Friedel-Crafts alkylation, the You group extended this transformation to the use of indoles as heteroaromatic nucleophiles (Scheme 11). iV-Sulfonylated aldimines 28 are activated with the help of catalytic amounts of BINOL phosphate (5)-3k (10 mol%, R = 1-naphthyl) for the reaction with unprotected indoles 29 to provide 3-indolyl amines 30 in good yields (56-94%) together with excellent enantioselec-tivities (58 to >99% ee) [21], Antilla and coworkers demonstrated that A-benzoyl-protected aldimines can be employed as electrophiles for the addition of iV-benzylated indoles with similar efficiencies [22]. Both protocols tolerate several aryl imines and a variety of substituents at the indole moiety. In addition, one example of the use of an aliphatic imine (56%, 58% ee) was presented. 

List and coworkers reasoned that BINOL phosphates (specific Brpnsted acid catalysis) could be suitable catalysts for an asymmetric direct Pictet-Spengler reaction [26], Preliminary experiments revealed that unsubstituted tryptamines do not undergo the desired cyclization. Introduction of two geminal ester groups rendered the substrates more reactive which might be explained by electronic reasons and a Thorpe-Ingold effect. Tryptamines 39 reacted with aldehydes 40 in the presence of phosphoric acid (5)-3o (20 moI%, R = bearing 2,4,6-triisopropyI-... 

In 2007, Hiemstra et al. established a catalytic asymmetric Pictet-Spengler reaction that proceeds via (V-sulfenyliminium ions (Scheme 15) [27], Treatment of iV-sulfenylated tryptamines 42 with aldehydes 40 and BINOL phosphate (R)-3f (5 mol%, R = 3,5-(CF3)2-CgH3) afforded tetrahydro-P-carbohnes. After completion of the cyclization the sulfenyl group was cleaved by the use of HCl. This one-pot... 

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). 

Two years later, Terada and coworkers described an asymmetric organocatalytic aza-ene-type reaction (Scheme 28) [50], BINOL phosphate (7 )-3m (0.1 mol%, R = 9-anthryl) bearing 9-anthryl substituents mediated the reaction of A-benzoylated aldimines 32 with enecarbamate 76 derived from acetophenone. Subsequent hydrolysis led to the formation of P-amino ketones 77 in good yields (53-97%) and excellent enantioselectivities (92-98% ee). A substrate/catalyst ratio of 1,000 1 has rarely been achieved in asymmetric Brpnsted acid catalysis before. 

In 2007, Rneping et al. found chiral H -BINOL phosphate (R)-141 (10 mol%, R = 9-phenanthryl) with 9-phenanthryl groups to mediate the reaction of aldimines 11 with A-methylenepyrroUdin-l-amine (81a) (Scheme 30) [52]. A-Boc-protected a-amino hydrazones 82 were obtained in satisfactory yields (48-82%) and enanti-oselectivities (74-90% ee). 

Akiyama et al. disclosed an asymmetric hydrophosphonylation in 2005 (Scheme 32) [55], Addition of diisopropyl phosphite (85a) to A-arylated aldimines 86 in the presence of BINOL phosphate (R)-M (10 mol%, R = 3,5-(CF3)j-C Hj) afforded a-amino phosphonates 87 in good yields (72-97%). The enantioselectivities were satisfactory (81-90% ee) in the case of imines derived from a,(3-unsaturated aldehydes and moderate (52-77% ee) for aromatic substrates. 

Three years later. List and coworkers extended their phosphoric acid-catalyzed dynamic kinetic resolution of enoUzable aldehydes (Schemes 18 and 19) to the Kabachnik-Fields reaction (Scheme 33) [56]. This transformation combines the differentiation of the enantiomers of a racemate (50) (control of the absolute configuration at the P-position of 88) with an enantiotopic face differentiation (creation of the stereogenic center at the a-position of 88). The introduction of a new steri-cally congested phosphoric acid led to success. BINOL phosphate (R)-3p (10 mol%, R = 2,6- Prj-4-(9-anthryl)-C H3) with anthryl-substituted diisopropylphenyl groups promoted the three-component reaction of a-branched aldehydes 50 with p-anisidine (89) and di-(3-pentyl) phosphite (85b). P-Branched a-amino phosphonates 88 were obtained in high yields (61-89%) and diastereoselectivities (7 1-28 1) along with good enantioselectivities (76-94% ee) and could be converted into... 

Three years later, the same group showed that oxygen-containing nucleophiles can also be used (Scheme 35) [58], IV-Benzoylated aldimines 32 were treated with alcohols 92 in the presence of chiral BINOL phosphate R)-3m (5 mol%, R = 9-anthryl) to provide iV,0-aminals 93 in high yields (62-99%) and good enantiose-lectivities (65-95% ee). 

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. 

The same group expanded the scope of the aza-Diels-Alder reaction of electron-rich dienes to Brassard s diene 97 (Scheme 37) [60]. In contrast to Danishefsky s diene, it is more reactive, but less stable. Akiyama et al. found chiral BINOL phosphate (R)-3m (3 mol%, R = 9-anthryl) with 9-anthryl substituents to promote the [4 + 2] cycloaddition of A-arylated aldimines 94 and Brassard s diene 97. Subsequent treatment with benzoic acid led to the formation of piperidinones 98. Interestingly, the use of its pyridinium salt (3 mol%) resulted in a higher yield (87% instead of 72%) along with a comparable enantioselectivity (94% ee instead of 92% ee). This method furnished cycloadducts 98 derived from aromatic, heteroaromatic, a,P-unsaturated, and aliphatic precursors 94 in satisfactory yields (63-91%) and excellent enantioselectivities (92-99% ee). NMR studies revealed that Brassard s diene 97 is labile in the presence of phosphoric acid 3m (88% decomposition after 1 h), but comparatively stable in the presence of its pyridinium salt (25% decomposition after 1 h). This observation can be explained by the fact that the pyridinium salt is a weak Brpnsted acid compared to BINOL phosphate 3m. 

On the one hand. Rueping s protocol involved a combination of chiral BINOL phosphate (R)-3j (10 mol%, R = 2-naphthyl) bearing 2-naphthyl substituents and achiral acetic acid (20 mol%) [62], While stronger Brpnsted acid 3j is expected to activate electrophile 86, the weaker Brpnsted acid is proposed to facilitate the keto-enol tautomerism of nucleophile 101 (Scheme 40). On the other hand, Gong... 

In 2008, Gong and coworkers introduced a new chiral bisphosphoric acid 19 (Fig. 4) that consists of two BINOL phosphates linked by an oxygen atom for a three-component 1,3-dipolar cycloaddition (Scheme 42) [66]. Aldehydes 40 reacted with a-amino esters 105 and maleates 106 in the presence of Brpnsted acid 19 (10 mol%) to afford pyrrolidines 107 as endo-diastereomers in high yields (67-97%) and enantioselectivities (76-99% ee). This protocol tolerated aromatic, a,P-unsaturated, and aliphatic aldehydes. Aminomalonates as well as phenylglycine esters could be employed as dipolarophiles. 

Recently, several research gronps reported on the use of chiral BINOL phosphates as Brpnsted acid catalysts in MCRs involving imine activation. 

Simple phenyl substituents at the 3,3 -positions were sufficient to achieve high levels of enantiocontrol, which is in contrast to the substitution effect of many other BINOL phosphate-catalyzed reactions. Indeed, increasing the size of the 3,3 -sub-stituents resulted in both decreased yields and enantioselectivities. The synthetic utility of the catalytic asymmetric Biginelli reaction was demonstrated by the preparation of the active pharmaceutical ingredient monastrol (110a) in two steps... 

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]. 

In 2007, Terada et al. extended their previously described chiral phosphoric acid-catalyzed aza-ene-type reaction of M-acyl aldimines with disubstituted enecarbamates (Scheme 28) to a tandem aza-ene-type reaction/cyclization cascade as a one-pot entry to enantioenriched piperidines 121 (Scheme 48). The sequential process was rendered possible by using monosubstituted 122 instead of a disubstituted enecarbamate 76 to produce a reactive aldimine intermediate 123, which is prone to undergo a further aza-ene-type reaction with a second enecarbamate equivalent. Subsequent intramolecular cychzation of intermediate 124 terminates the sequence. The optimal chiral BINOL phosphate (R)-3h (2-5 mol%, R = 4-Ph-C H ) provided the 2,4,6-sub-stituted M-Boc-protected piperidines 121 in good to exceUent yields (68 to > 99%) and accomplished the formation of three stereogenic centers with high diastereo- and exceUent enantiocontrol (7.3 1 to 19 1 transicis, 97 to > 99% ee(trans)) [72]. 

In 2007, two groups independently described asymmetric phosphoric acid-catalyzed Friedel-Crafts alkylations of indoles. While You et al. chose the conventional approach and employed imines as substrates (Scheme 11), Terada and coworkers came up with a different concept and used electron-rich alkenes as precursors (Scheme 49) [73]. Enecarbamates 125 reacted with indoles 29 in the presence of BINOL phosphate (R)-io (5 mol%, R = bearing 2,4,6-triisopropyl-... 

BINOL phosphate (5)-3o (10 mol%, R = 2,4,6- PTj-C Hj) turned out to be the catalyst of choice and gave iV-acetylated 3-indolyl amines 128 bearing a qnatemary stere-ogenic center in excellent yields (94-99%) with high enantioselectivities (73-97% ee). Enamides derived from aryl-methyl ketones as well as indoles with varions substitnents conld be employed. 

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. 

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). 

TRANSFER HYDROGENATION USING CHIRAL BINOL-PHOSPHATES AS CATALYSTS. 162... 

Phenylquinoline (20.0 mg 0.097 mmol), BINOL-phosphate 1 (1.4 mg, 2 mol %), Hantzsch dihydropyridine (59.2 mg, 0.234 mmol) and benzene (2.0 mL) were added to a screw-capped vial and the mixture was exposed to an argon atmosphere. The resulting yellow solution was allowed to stir at 60 °C for 12 h. The solvent was evaporated in vacuo, and the residue was purified by column chromatography over silica gel to afford the amine as yellow oil (92 %, 97 % ee). 

Benzo[l,3]dioxol-5-yl-ethyl)-quinoline (20.0mg 0.072 mmol), BINOL-phosphate 1 (0.5 mg, Imol %), Hantzsch dihydropyridine (43.8 mg,... 

An enantioselective version of this reaction has been reported by Rueping et al.102 Treatment of an a-iminoester and an alkyne with silver acetate and a binol phosphate derivative gave propargylic amines with the highest enantiomeric ratio (er) reported as 96 4. Although the proposed catalytic cycle invoked the in situ formation of the... 

With the chiral BINOL-phosphates in hand we started to examine the enantioselective transferhydrogenation of ketimines 1. After reaction optimization, including a survey of different solvents, temperatures, BINOL-phosphates, and Hantzsch dihydropyridines, we found that indeed enantioselectivities are observed and the best selectivities are obtained with Brpnsted acid 5a and Hantzsch ester 2a (Table 2). In general, for the first time, high enantioselectivities and good yields are observed in this newly developed metal-free reduction procedure (Rueping et al. 2005b Hofmann et al. 2005 Storer et al. 2006). 

The absolute configuration of the amine 7 may be explained by a stereochemical model based on the X-ray crystal structure of the chiral BINOL-phosphate (Fig. 4). In the transition state the ketimine is activated by the Brpnsted acid in such a way, that the nucleophile has to approach from the less hindered si face as the re face is effectively shielded by the large aryl substituent of the catalyst (Fig. 4, left). Furthermore, a bifunctional activation seems to be plausible, where next to the ketimine protonation, the dihydropyridine is activated through a hydrogen bond from the Lewis basic oxygen of the phosphoryl group. 

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