Alkylations asymmetric, chiral phase-transfer

Efficient Asymmetric Alkylations via Chiral Phase-Transfer Catalysis Applications and Mechanism... 

Figure 3. Asymmetric alkylations with chiral phase transfer catalysts.

The asymmetric alkylation of cyclic ketones, imines of glycine esters, and achiral, enolizable carbonyl compounds in the presence of chiral phase-transfer organoca-talysts is an efficient method for the preparation of a broad variety of interesting compounds in the optically active form. The reactions are not only highly efficient, as has been shown impressively by, e.g., the synthesis of enantiomerically pure a-amino acids, but also employ readily available and inexpensive catalysts. This makes enantioselective alkylation via chiral phase-transfer catalysts attractive for large-scale applications also. A broad range of highly efficient chiral phase-transfer catalysts is also available. 

Dolling, U. H., D. L. Hughes, A. Bhattacharya, K. M. Ryan, S. Karady, L. M. Weinstock, V. J. Grenda, and E. J. J. Grabowski, Efficient Asymmetric Alkylations via Chiral Phase-Transfer Catalysis Applications and Mechanism, Phase-Transfer Cctalysis New Chemistry, Catalysts, and AppUcatwns, C. M. Starks, ed., ACS... 

Table 3.11. O Donnell s asymmetric glycine alkylations by chiral phase transfer catalysis (Scheme 3.26b [151]).

This synthesis, which was reported by a group of development chemists, represents a remarkably efficient application of asymmetric alkylation by chiral phase transfer catalysis (PTC) (see section 6.1.1). Reaction of indanone (77) and allylic halide (78) under PTC conditions in the presence of only a few per cent of chiral cinchonidine derivative... 

The first practical and efficient asymmetric alkylation by use of chiral phase-transfer catalysts was the alkylation of the phenylindanone 15 (R1=Ph), reported by the Merck research group in 1984.114-161 By use of the quaternary ammonium salt 7 (R=4-CF3i X=Br) derived from cinchonine, the alkylated products 16 were obtained in excellent yield with high enantiomeric excess, as shown in... 

W. Nerinckx, M. Vandewalle, Asymmetric Alkylation of a-Aryl Substituted Carbonyl Compounds by Means of Chiral Phase Transfer Catalysts. Applications for the Synthesis of (+)-Podocarp-8(14)-en-13-one and of (-)-Wy-16,225, A Potent Analgesic Agent , Tetrahedron Asymmetry 1990,1, 265-276. 

Belokon et al. (261) subsequently found that salen-Cu(II) complexes are effective catalysts for the asymmetric alkylation of amino acid derivatives. Excellent se-lectivities are observed with 1 mol% of 88b-Cu in toluene at ambient temperature, Eq. 225. Although no stereochemical model is advanced to account for the selec-tivities, these workers suggest the catalyst may be acting as a chiral phase-transfer agent. 

Catalytic asymmetric methylation of 6,7-dichloro-5-methoxy-2-phenyl-l-indanone with methyl chloride in 50% sodium hydroxide/toluene using M-(p-trifluoro-methylbenzyDcinchoninium bromide as chiral phase transfer catalyst produces (S)-(+)-6,7-dichloro-5-methoxy-2-methyl-2--phenyl-l-indanone in 94% ee and 95% yield. Under similar conditions, via an asymmetric modification of the Robinson annulation enqploying 1,3-dichloro-2-butene (Wichterle reagent) as a methyl vinyl ketone surrogate, 6,7 dichloro-5-methoxy 2-propyl-l-indanone is alkylated to (S)-(+)-6,7-dichloro-2-(3-chloro-2-butenyl)-2,3 dihydroxy-5-methoxy-2-propyl-l-inden-l-one in 92% ee and 99% yield. Kinetic and mechanistic studies provide evidence for an intermediate dimeric catalyst species and subsequent formation of a tight ion pair between catalyst and substrate. 

Asymmetric Alkylation of Enolates Mediated by Chiral Phase Transfer... 

There are only a few reports on chiral phase transfer mediated alkylations". This approach, which seems to offer excellent opportunities for simple asymmetric procedures, has been demonstrated in the catalytic, enantioselective alkylation of racemic 6,7-dichloro-5-methoxy-2-phenyl-l-indanone (1) to form ( + )-indacrinone (4)100. /V-[4-(tnfluoromethyl)phenylmethyl]cinchoninium bromide (2) is one of the most effective catalysts for this reaction. The choice of reaction variables is very important and reaction conditions have been selected which afford very high asymmetric induction (92% cc). A transition state model 3 based on ion pairing between the indanone anion and the benzylcinchoninium cation has been proposed 10°. 

While alkyl halides are typically employed as an electrophile for this transformation, Takemoto developed palladium-catalyzed asymmetric allylic alkylation of 1 using allylic acetates and chiral phase-transfer catalyst 4k, as depicted in Scheme 2.5 [ 2 3 ]. The choice of triphenyl phosphite [(PhO)3P] as an achiral palladium ligand was crucial to achieve high enantioselectivity. 

Jew, Park and coworkers performed systematic investigations to develop a more efficient system for the asymmetric synthesis of a-alkylalanines by chiral phase-transfer catalysis [31]. Eventually, sterically more demanding 2-naphthyl aldi-mine tert-butyl ester 14 was identified as a suitable substrate, and its alkylation in the presence of stronger base rubidium hydroxide (RbOH) and 0(9)-allyl-N-2, 3, 4 -trifluorobenzyldihydrocinchonidinium bromide (6a) at lower reaction temperature led to the highest enantioselectivity (Scheme 2.11). 

Takemoto and coworkers extended their palladium-catalyzed asymmetric allylic alkylation strategy using allyl acetate and chiral phase-transfer catalyst to the quaternization of 13 [23b]. A correct choice of the achiral palladium ligand, (PhO P, was again crucial to achieve high enantioselectivity and hence, without chiral phosphine ligand on palladium, the desired allylation product 15 was obtained with 83% ee after hydrolysis of the imine moiety with aqueous citric acid and subsequent benzoylation (Scheme 2.12). 

Enantioselective Michael addition of glycine derivatives by means of chiral phase-transfer catalysis has been developed to synthesize various functionalized a-alkyl-a-amino acids. Corey utilized 4d as catalyst for asymmetric Michael addition of glycinate Schiff base 1 to a,(3-unsaturated carbonyl substrates with high enantioselectivity (Scheme 2.15) [35,36]. With methyl acrylate as an acceptor, the a-tert-butyl-y-methyl ester of (S)-glutamic acid can be produced, a functionalized glutamic acid... 

The salient feature of le as a chiral phase-transfer catalyst is its ability to catalyze the asymmetric alkylation of glycine methyl and ethyl ester derivatives 4 and 5 with excellent enantioselectivities. Since methyl and ethyl esters are certainly more susceptible towards nucleophilic additions than tert-butyl ester, the synthetic advantage of this process is clear, and highlighted by the facile transformation of the alkylation products (Scheme 5.3) [8],... 

The Maruoka group s further efforts toward simplification of the catalyst have led to the design of new, polyamine-based chiral phase-transfer catalysts of type 15, with expectation of the multiplier effect of chiral auxiliaries, as illustrated in Scheme 5.10 [13]. The chiral efficiency of such polyamine-based chiral phase-transfer catalysts (S)-15 was examined by carrying out an asymmetric alkylation of glycine derivative 2 under phase-transfer conditions. Among various commercially available polyamines, spermidine- and spermine-based polyammonium salts were found to show moderate enantioselectivity. In particular, the introduction of a 3,4,5-trifluor-ophenyl group at the 3,3 -positions of chiral binaphthyl moieties showed excellent asymmetric induction. 

The enantioselective synthesis of a-amino acids employing easily available and reusable chiral catalysts or reagents presents clear advantages for large-scale applications. Accordingly, recyclable fluorous chiral phase-transfer catalyst 31 has been developed by the authors group, and its high chiral efficiency and reusability demonstrated in the asymmetric alkylation of 2. After the reaction, 31 could be easily recovered by simple extraction with FC-72 (perfluorohexanes) as a fluorous solvent and used for the next run, without any loss of reactivity and selectivity (Scheme 5.17) [23]. 

The chiral phase-transfer catalysis of le was further applied to the facile synthesis of L-Dopa ester and its analogue, which usually have been prepared by either asymmetric hydrogenation of eneamides or enzymatic processes, and tested as potential drugs for the treatment of Parkinson s disease. Phase-transfer-catalyzed alkylation of 2 with the requisite benzyl bromide 35a in toluene-50% KOH aqueous solution proceeded smoothly at 0 °C under the influence of (R,R)-le to furnish fully protected L-Dopa tert-butyl ester this was subsequently hydrolyzed to afford the corresponding amino ester 36a in 81% yield with 98% ee. Debenzylation of 36a under... 

Since the aldimine Schiff base 21 can be readily prepared from glycine, direct stereoselective introduction of two different side chains to 21 by appropriate chiral phase-transfer catalysis would provide an attractive, yet powerful, strategy for the asymmetric synthesis of structurally diverse a,a-dialkyl-a-amino acids. This possibility of a one-pot asymmetric double alkylation has been realized by using N-spiro chiral quaternary ammonium bromide le (Scheme 5.21). 

The highly enantioselective alkylation of a-substituted a-cyanoacetates was achieved using chiral phase-transfer catalysts of type le and lh to afford a,a-disubstituted a-cyanoacetates possessing an asymmetric quaternary carbon center with high enantioselectivity, as shown in Table 5.9 [34]. 

Consequently, Dehmlow and coworkers modified the cinchona alkaloid structure to elucidate the role of each ofthe structural motifs of cinchona alkaloid-derived chiral phase-transfer catalysts in asymmetric reactions. Thus, the quinoline nucleus of cinchona alkaloid was replaced with various simple or sterically bulky substituents, and the resulting catalysts were screened in asymmetric reactions (Scheme 7.2). The initial results using catalysts 8-11 in the asymmetric borohydride reduction of pivalophenone, the hydroxylation of 2-ethyl-l-tetralone and the alkylation of SchifF s base each exhibited lower enantiomeric excesses than the corresponding cinchona alkaloid-derived chiral phase-transfer catalysts [14]. 

The asymmetric alkylation of SchifPs base ester using a chiral phase-transfer catalyst to produce a-amino adds is one of the most widely studied reactions. This reaction is generally used as a test reaction to design new, effident chiral... 

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