Asymmetric Phase-transfer Catalysis PTC

R = hydrogen, methoxy R = hydrogen, allyl, benzyl, etc. R = vinyl, ethyl R = methyl, benzyl, substituted benzyl, anthracenylmethyl. etc. 

The same authors conducted systematic studies of a-methylation and proposed the tight ion-pair complex 4 as an intermediate, formed through hydrogen bonding and electrostatic n-n stacking interactions, accounting for the chiral induction. Enantioselective a-methylation has been recognised as the first attempt at asymmetric phase-transfer catalytic all lation in the presence of a quaternary ammonium salt prepared from cinchonine as a catalyst. 

1 Monoallfylation of Schiff Bases Derived from Gtycine 

Five years after the successful application of the cinchonine-derived quaternary ammonium catalyst 3 by the Merck research group, O Donnell and 

O Donnell s pioneering studies were reported, the catalytic efficiency of newly developed phase-transfer catalysts has been evaluated by the alkylation of glycine Schiff base 5 and for these catalysts the particular allqrlation studied and enantiomeric excess will be given in parentheses during the discussion of the catalyst. 

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The epoxidation of enones using chiral phase transfer catalysis (PTC) is an emerging technology that does not use transition metal catalysts. Lygo and To described the use of anthracenylmethyl derivatives of a cinchona alkaloid that are capable of catalyzing the epoxidation of enones with remarkable levels of asymmetric control and a one pot method for oxidation of the aUyl alcohol directly into... 

In particular, it is not only the cinchona alkaloids that are suitable chiral sources for asymmetric organocatalysis [6], but also the corresponding ammonium salts. Indeed, the latter are particularly useful for chiral PTCs because (1) both pseudo enantiomers of the starting amines are inexpensive and available commercially (2) various quaternary ammonium salts can be easily prepared by the use of alkyl halides in a single step and (3) the olefin and hydroxyl functions are beneficial for further modification of the catalyst. In this chapter, the details of recent progress on asymmetric phase-transfer catalysis are described, with special focus on cinchona-derived ammonium salts, except for asymmetric alkylation in a-amino acid synthesis. 

In the Michael-addition, a nucleophile Nu is added to the / -position of an a,fi-unsaturated acceptor A (Scheme 4.1) [1], The active nucleophile Nu is usually generated by deprotonation of the precursor NuH. Addition of Nu to a prochiral acceptor A generates a center of chirality at the / -carbon atom of the acceptor A. Furthermore, the reaction of the intermediate enolate anion with the electrophile E+ may generate a second center of chirality at the a-carbon atom of the acceptor. This mechanistic scheme implies that enantioface-differentiation in the addition to the yfi-carbon atom of the acceptor can be achieved in two ways (i) deprotonation of NuH with a chiral base results in the chiral ion pair I which can be expected to add to the acceptor asymmetrically and (ii) phase-transfer catalysis (PTC) in which deprotonation of NuH is achieved in one phase with an achiral base and the anion... 

The asymmetric alkylation of glycine derivatives is one of the most simple methods by which to obtain optically active a-amino acids [31]. The enantioselective alkylation of glycine Schiff base 52 under phase-transfer catalysis (PTC) conditions and catalyzed by a quaternary cinchona alkaloid, as pioneered by O Donnell [32], allowed impressive degrees of enantioselection to be achieved using only a very simple procedure. Some examples of polymer-supported cinchona alkaloids are shown in Scheme 3.14. Polymer-supported chiral quaternary ammonium salts 48 have been easily prepared from crosslinked chloromethylated polystyrene (Merrifield resin) with an excess of cinchona alkaloid in refluxing toluene [33]. The use of these polymer-supported quaternary ammonium salts allowed high enantioselectivities (up to 90% ee) to be obtained. 

One class of application that readily highlights the enormous potential of asymmetric phase-transfer catalysis is the stereoselective ot-alkylation of different carbanion nucleophiles, in particular enolates. Although these types of transformations are most important in organic chemistry, there are stiU only a limited number of stereoselective catalytic methods available and the use of chiral PTCs represents one of the most versatile strategies to achieve such transformations. One example of special interest is the asymmetric a-alkylation of glycine Schiffbase 374 (Scheme 85)... 

The paramount importance of Michael additions as versatile C-C bond forming transformations was discussed in some detail earlier in this volume. Thus, it is not surprising that, besides the use of chiral PTCs in asymmetric a-alkylation reactions, their use for stereoselective Michael additions is one of the most carefully investigated reactions in asymmetric phase-transfer catalysis (328, 329). Accordingly, the additional use of this methodology in asymmetric total synthesis has been reported on several occasions. 

The Wichterle reagent has also been employed in enantioselective Robinson annulations involving the use of phase-transfer catalysis (PTC). Bhattacharya and co-workers had previously investigated the asymmetric alkylation of inadanones, such as 59, using substituted N-benzylcinchoninium salts realizing their ability to produce enantio-enriched... 

Building upon these concepts, this chapter firstly gives an insight into the modes of action of a selection of non-covalent chiral organocatalysts, employing chiral Brpnsted acid catalysis, chiral Brpnsted base catalysis, and chiral phase-transfer catalysis (PTC). Further sections of this chapter describe two separate case studies that aim to compare and contrast selected covalent and non-covalent strategies for achieving two distinct processes, acyl transfer reactions and asymmetric pericyclic processes. 

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 introduction of a new catalyst system by Maruoka and coworkers using C2-symmetric binaphthyl-based chiral spiro ammonium salts 6 in 1999, paved the way for a new era in asymmetric phase-transfer catalysis. This PTC system was found to be highly effective for a variety of asymmetric transformations (e.g., Michael additions, a-amino acid syntheses, epoxidations. 

M. J. O Donnell, Asymmetric PTC Reactions. Part 1 Amino Acids , Phases - The Sachem Phase Transfer Catalysis Review 1998, Issue 4, pp. 5-8. 

Treatment of diethyl malonate and related compounds with 1,2-dihaloethane in the presence of base constitutes a classical method of cyclopropane synthesis296"300. The reaction can be conveniently carried out under PTC conditions. An improved method utilizing solid-liquid phase transfer catalysis has been reported298. The reaction of dimethyl or diethyl malonate with 1,2-dibromoalkanes except for 1,2-dibromethane tends to give only low yields of 2-alkylcyclopropane-l, 1-dicarboxylic esters. By the use of di-tm-butyl malonate, their preparations in satisfactory yields are realized (equation 134)297. The 2-alkylcyclopropane derivatives are also obtained from the reaction of dimethyl malonate and cyclic sulfates derived from alkane-1,2-diols (equation 135)301. Asymmetric synthesis... 

Catalytic Michael additions of a-nitroesters 38 catalyzed by a BINOL (2,2 -dihydroxy-l,r-bi-naphthyl) complex were found to yield the addition products 39 as precursors for a-alkylated amino acids in good yields and with respectable enantioselectivities (8-80%) as shown in Scheme 9 [45]. Asymmetric PTC (phase transfer catalysis) mediated by TADDOL (40) as a chiral catalyst has been used to synthesize enantiomeri-cally enriched a-alkylated amino acids 41 (up to 82 % ee) [46], A similar strategy has been used to access a-amino acids in a stereoselective fashion [47], Using azlactones 42 as nucleophiles in the palladium catalyzed stereoselective allyla-tion addition, compounds 43 were obtained in high yields and almost enantiomerically pure (Scheme 9) [48]. The azlactones 43 can then be converted into the a-alkylated amino acids as shown in Scheme 4. 

The synthesis of the chiral copper catalyst is very easy to reproduce. The complex catalyses the asymmetric alkylation of enolates of a range of amino acids, thus allowing the synthesis of enantiomeric ally enriched a,a disubstituted amino acids with up to 92% ee. The procedure combines the synthetic simplicity of the Phase Transfer Catalyst (PTC) approach, with the advantages of catalysis by metal complexes. The chemistry is compatible with the use of methyl ester substrates, thus avoiding the use of iso-propyl or ferf-butyl esters which are needed for cinchona-alkaloid catalyzed reactions[4], where the steric bulk of the ester is important for efficient asymmetric induction. Another advantage compared with cinchona-alkaloid systems is that copper(II)(chsalen) catalyses the alkylation of substrates derived from a range of amino acids, not just glycine and alanine (Table 2.4). 

The Plaquevent group achieved a new and efficient method for the approach to both enantiomers of methyl dihydrojasmonate 47 by asymmetric Michael addition under solid-liquid phase-transfer catalysis. The main advantages of their procedure are the solvent-free system and the creation of two contiguous stereogenic centres in one step. The authors proposed a plausible mechanism with a transition state composed of substrate 45 and catalyst, quinine-, or quinidine-derived PTC catalyst (48a, 49a), in which hydrogen bonding ensures the proximity of the reactive centres and significantly stabilises the transition state (Scheme 16.14). ... 

Many studies of asymmetric chemical conversions through the catalysis of Cinchona-derived PTC catalysts have been performed to expand the application of phase-transfer catalysis to various organic reactions. In addition to the reactions classified above, some selected examples of asymmetric phase-transfer reactions are shown below. 

Phase-transfer catalysis is one of the most practical synthetic methodologies because of its operational simplicity and mild reaction conditions, which enable applications in industrial syntheses as a sustainable green chemical process. As reviewed in this chapter, diverse Cinchona alkaloid-derived quaternaiy ammonium salts have been developed via the modification of Cinchona alkaloids based on steric or electronic factors as highly efficient chiral PTC catalysts and successfully applied in various asymmetric organic reactions. Despite the successful development and application of these catalysts, some problems remain to be addressed. Although Cinchona alkaloids have unique structural features, resulting in the availability of four... 

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