Imines arylation, asymmetric

Rhodium Phosphine-Catalyzed Arylation of Imines The asymmetric rho... 

Ru has been used frequently for obtaining chiral amine units, in asymmetric transfer hydrogenations of imine substrates [40], aldol-type reactions with imine electrophiles [41], and C-H bond arylation (see Chapter 4) [42]. There are very few reports in the literature on the use of ruthenium cattilysts for imine arylation. 

As far as we are aware, there have been no other reports on the arylation of imine substrates with ruthenium catalysts, besides our own work. In 2012, we published our efforts at developing a Ru-catalyzed asymmetric catalytic imine arylation with organoboron reagents and with chiral phosphane and new NHC-type ligands (Scheme 6.33) [44]. 

The Schaus group also reported related reactions involving asymmetric allyl-boration of acyl imines [59], asymmetric three component Petasis condensation reaction of secondary amines/glyoxylates/alkenyl boronates [60], as well as addition of aryl, vinyl, and alkynyl boronates to acyl imines (Fig. 15) [61]. In the later reaction, a two point coordination transition state was proposed to account the observed facial selectivity. 

Bolm et al. [108] prepared a C2-symmetric bis (sulfoximine) as ligand for the copper-catalyzed hetero-Diels-Alder reaction. The stereogenic sulfur atom being located near the AT-coordinating atom, these structures were assumed to be promising for asymmetric catalysis. Their Hgand (79 in Scheme 43) was synthesized by palladium-catalyzed N-aryl imination from 1,2-dibromobenzene and (S)-S-methyl-S-phenylsulfoximine with Pd2dba3 in 70% yield. 

So far, there is only one report describing the use of chiral NHC-metal complexes in catalytic asymmetric arylation of imines. This was achieved by using C -symmetric cationic NHC-Pd diaquo complex 20 (Scheme 7.6) [38]. The arylation of a variety of A-tosylimines with different arylboronic acids was carried out under mild conditions. The presence of electron-withdrawing or electron-donating substituents on both partners did not seem to affect the reaction and the corresponding chiral diarylamines were obtained in good to excellent yields and high enantiomeric excess. 

Bode and co-workers have extended the synthetic ntility of homoenolates to the formation of enantiomerically enriched IV-protected y-butyrolactams 169 from saccharin-derived cyclic sulfonylimines 167. While racemic products have been prepared from a range of P-alkyl and P-aryl substitnted enals and substitnted imi-nes, only a single example of an asymmetric variant has been shown, affording the lactam prodnct 169 with good levels of enantioselectivity and diastereoselectivity (Scheme 12.36) [71], As noted in the racemic series (see Section 12.2.2), two mechanisms have been proposed for this type of transformation, either by addition of a homoenolate to the imine or via an ene-type mechanism. 

Ojima, 1., Habus, 1., Zhao, M. (1991) Efficient and Practical Asymmetric Synthesis ofthe Taxol C-13 Side Chain, N-Benzoyl-(2R,3S)-3-phenylisoserine, and its Analogues via Chiral 3-Hydroxy-4-aryl-b-lactams Through Chiral Ester Enolate-Imine Cyclocondensation. Journal of Organic Chemistry, 56, 1681-1683. 

Acid- and base-promoted methods have also been used in the syntheses of pyrazoles. Hydrogenation of methyl 2-Cbz(hydrazine)-3-hydroxy-4,4-dimethoxybutanoate 11 followed by cyclization in the presence of trifluoroacetic acid afforded the first asymmetric synthesis of the (4S,5.R)-5-carbomethoxy-4-hydroxy-A2-pyrazoline 12 <00TL8795>. Reaction of 2-nitrobenzyl triphenylphosphonium ylide (13) with aiyl isocyanates afforded 2-aryl-2H-indazoles 14 <00TL9893>. Base-promoted reaction of nitrobenzenes 15 with aryl imines 16 afforded aryl pyrazoles 17 . 

The more recently reported Zr-catalyzed asymmetric alkylation of aliphatic imines is shown in Scheme 6.18 [58]. Several important principles merit specific mention. (1) The catalytic asymmetric protocol can readily be applied to the synthesis of non-aryl im-... 

Catalytic asymmetric cyanide addition to imines constitutes an important C—C bondforming reaction, as the product amino nitriles may be converted to non-proteogenic a-amino acids. Kobayashi and co-workers have developed two different versions of the Zr-catalyzed amino nitrile synthesis [73]. The first variant is summarized in Scheme 6.22. The bimetallic complex 65, formed from two molecules of 6-Br-binol and one molecule of 2-Br-binol in the presence of two molecules of Zr(OtBu)4 and N-methylimidazole, was proposed as the active catalytic species. This hypothesis was based on various NMR studies more rigorous kinetic data are not as yet available. Nonetheless, as depicted in Scheme 6.22, reaction of o-hydroxyl imine 66 with 5 mol% 65 and 1—1.5 equiv. Bu3SnCN (CH2C12, —45 °C) leads to the formation of amino nitrile 67 with 91 % ee and in 92 % isolated yield. As is also shown in Scheme 6.22, electron-withdrawing (— 68) and electron-rich (—> 69), as well as more sterically hindered aryl substituents (— 70) readily undergo asymmetric cyanide addition. 

Asymmetric reductions. The reagent can effect asymmetric reduction of alkyl aryl ketones and unhindered dialkyl ketones in high optical yield.1 It is the most useful reagent known to date for asymmetric reduction of even hindered a-keto esters to (S)-a-hydroxy esters in >90% ee.2 It is also effective for asymmetric reduction of phosphinyl imines of dialkyl ketones, RlR2C=NP(0)(C6H5)2 (50-84% ee).3... 

Binol-derived phosphoroamidite PipPhos (19) has been successfully used as a ligand for the Ir-catalyzed asymmetric hydrogenation of 2- and 2,6-substituted quinolines [39], 2- and 2,6-substituted quinoxalines [40], and IV-aryl imines [41] (Fig. 16). 

Andersson reported the use of ligand 13a in the asymmetric hydrogenation of substituted acetophenone-based 77-aryl imines (Table 18) [88, 89]. New ligands 84 and 85 were reported by the groups of Bolm and Knochel, respectively, for... 

Ab initio calculations on aza-Diels-Alder reactions of electron-deficient imines with buta-l,3-diene show that these reactions are HOMO (diene)-LUMO(dienophile)-controlled and that electron-deficient imines should be more reactive than alkyl-or aryl-imines. The Diels-Alder reaction of r-butyl 2//-azirine-3-carboxylate (80) proceeds with high diastereoselectivity with electron-rich dienes (81) (Scheme 28). The hetero-Diels-Alder additions of imines with sterically demanding dienes yield perhydroquinolines bearing an angular methyl group. The asymmetric hetero-Diels-Alder reaction between alkenyloxazolines and isocyanates produces diastereometri-cally pure oxazolo[3,2-c]pyrimidines. °... 

Substituents on imino nitrogen influence both reactivity and enantioselectivity in hydrogenation of imino compounds. Figure 1.32 shows two successful examples. An f-BINAPHANE-Ir complex effects asymmetric hydrogenation of A-aryl aromatic imines.On the other hand, an Et-DuPHOS-Rh complex (see Figure 1.2) is effective for hydrogenation of A-acyUiydrazones. ... 

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. 

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. 

In 2007, Maruoka et al. introduced chiral dicarboxylic acids consisting of two carboxylic acid functionalities and an axially chiral binaphthyl moiety. They applied this new class of chiral Brpnsted acid catalyst to the asymmetric alkylation of diazo compounds withA-Boc imines [91]. The preparation of the dicarboxylic acid catalysts bearing aryl groups at the 3,3 -positions of the binaphthyl scaffold follows a synthetic route, which has been developed earlier in the Maruoka laboratory [92]. 

In 2008, the same group employed chiral dicarboxylic acid (R)-5 (5 mol%, R = 4- Bu-2,6-Me2-CgHj) as the catalyst in the asymmetric addition of aldehyde N,N-dialkylhydrazones 81 to aromatic iV-Boc-imines 11 in the presence of 4 A molecular sieves to provide a-amino hydrazones 176, valuable precursors of a-amino ketones, in good yields with excellent enantioselectivities (35-89%, 84-99% ee) (Scheme 74) [93], Aldehyde hydrazones are known as a class of acyl anion equivalents due to their aza-enamine structure. Their application in the field of asymmetric catalysis has been limited to the use of formaldehyde hydrazones (Scheme 30). Remarkably, the dicarboxylic acid-catalyzed method applied not only to formaldehyde hydrazone 81a (R = H) but also allowed for the use of various aryl-aldehyde hydrazones 81b (R = Ar) under shghtly modified conditions. Prior to this... 

Chiral dicarboxylic acid (R)-5g (5 mol%, R = Mes) bearing simpler mesityl-substituents at the 3,3 -positions was found to catalyze efficiently the trans-selective asymmetric aziridination of iV-aryl-monosubstituted diazoacetamides 177 and aromatic (V-Boc imines 11 (Scheme 75) [94], In sharp contrast to previous reports on this generally dx-selective sort of aziridination, this method exhibited unique fran -selectivity and afforded exclusively the fran -aziridines 178 in moderate to good yields along with excellent enantioselectivities (<20-71%, 89-99% ee). The 1,2-aryl shift products 179 were observed as side products in varying ratios (178 179= 56 44-90 10). Diazoacetamides were chosen instead of diazoesters. Due... 

VAPOL-derived phosphoric acid 11 was shown to catalyze the amidation of Boc-protected N-aryl imines with sulfonamide, phthaUmide, and maleimide nucleophiles to furnish the corresponding chiral aminals in excellent yields and ee s (Scheme 5.29) [52, 53]. This represents the first general catalytic and asymmetric... 

In Ught of the recent developments in thiourea, diol, and phosphoric-acid-mediated catalysis, far fewer studies have focused on the use of chiral carboxyhc acids as suitable hydrogen bond donors. To this end, Mamoka synthesized binaphthyl-derived dicarboxylic acid 49 which catalyzes the asymmetric Mannich reaction of N-Boc aryl imines and tert-diazoacetate (Scheme 5.65) [120]. The authors postulate that catalytic achvity is enhanced by the presence of an addihonal car-boxyhc acid moiety given that use of 2-napthoic acid as catalyst provided only trace amounts of product... 

While all of the aryl imine substrates examined for this Strecker methodology existed predominantly or exclusively as the E-isomers, this did not appear to be a requirement for high enantioselectivity as demonstrated in the asymmetric 42-cat-alyzed (2 mol% loading) hydrocyanation of the cyclic Z-imine 3,4-dihydroisoquino-line, which was converted to the corresponding adduct (88% yield, 91% cc) with the same sense of stereoinduction with respect to the benzylic stereogenic center as the examined acyclic E-imines (Schemes 6.41 and 6.42) [196]. 

Scheme 6.86 Typical 2-aryl-2,5-dihydropyrrole derivatives prepared with the asymmetric [3 + 2] cycloaddition between buta-2,3-dienoic acid ethyl ester and various DPP-protected (hetero)aromatic imines catalyzed by phosphinothiourea 75.

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