Phase-transfer catalysis, asymmetric

In contrast the progress of asymmetric synthesis by use of chiral non-racemic phase transfer catalysts had been slow compared to the ordinary phase transfer catalysis. However, recent achievements in this particular area are noteworthy and efficient asymmetric phase transfer catalysis has been increasingly explored.17 101... 

There are many examples on the asymmetric phase transfer catalysis, but highly efficient ones are not so many though they are increasing in recent years.17-101 This review will highlight the notable examples with emphasis on recent reports. 

Asymmetric Phase Transfer Catalysis Aldol Reactions... 

Epoxidation is another important area which has been actively investigated on asymmetric phase transfer catalysis. Especially, the epoxidation of various (i.)-a,p-unsaturated ketones 68 has been investigated in detail utilizing the ammonium salts derived from cinchonine and cinchonidine, and highly enantioselective and diastereoselective epoxidation has now been attained. When 30 % aqueons H202 was utilized in the epoxidation of various a, 3-unsaturated ketones 68, use of the 4-iodobenzyl cin-choninium bromide 7 (R=I, X=Br) together with LiOH in Bu20 afforded the a,p-epoxy ketones 88 up to 92% ee,1641 as shown in Table 5. The O-substituted... 

Numbers of asymmetric phase transfer catalysis can now be accomplished efficiently to give a variety of chiral non-racemic products with high enantiomeric excesses. Thus, asymmetric phase transfer catalysis has grown up into practical level in numbers of reactions and some optically pure compounds can be effectively produced on large scale by use of chiral phase transfer catalysts. 

In contrast to the maturity of asymmetric synthesis utilizing chiral transition metal catalysts, asymmetric phase transfer catalysis is still behind it and covers organic reactions to lesser extent. Thus, it is further necessary in wide range to explore efficient asymmetric phase transfer catalysis keeping its superiority of easy operation, mild reaction conditions, and environmental binignancy. 

The recent rapid progress in this area will definitely promise that asymmetric phase transfer catalysis is the reaction for the 21st century. 

R Lygo, J. Crosby, J. A. Peterson, Enantioselective Synthesis of Bis-a-Amino Add Esters via Asymmetric Phase-Transfer Catalysis , Tetrahedron Lett. 1999, 40, 1385-1388. 

Asymmetric phase-transfer catalysis using chiral nonra-cemic onium salts or crown ethers has now grown into a practical method whereby a large number of reactions can be performed and some optically pure compounds can be produced effectively on a large scale. 

Scheme 19 Synthesis of a Pyridoxal-Modified Alanine by Asymmetric Phase-Transfer Catalysis 53,541...

Asymmetric Phase Transfer Catalysis. Edited by Keiji Maruoka Copyright 2008 WILEY-VCH GmbH Co. KGaA, Weinheim ISBN 978-3-527-31842-1... 

The aim of this chapter is to assist the reader to generate an intuitive understanding of the mechanism of asymmetric phase-transfer catalysis, together with a practical guide for the design of such processes. More detailed studies related to the physical and numerical aspects of phase-transfer catalysis may be consulted elsewhere [3]. 

The representative reaction system applied in asymmetric phase-transfer catalysis is the biphasic system composed of an organic phase containing an acidic methylene or methine compound and an electrophile, and an aqueous or solid phase of inorganic base such as alkaline metal (Na, K, Cs) hydroxide or carbonate. The key reactive intermediate in this type of reaction is the onium carbanion species, mostly onium enolate or nitronate, which reacts with the electrophile in the organic phase to afford the product. 

The fate of the onium carbanion Q+R incorporated into the organic phase depends on the electrophilic reaction partner. The most studied area in the asymmetric phase-transfer catalysis is that of asymmetric alkylation of active methylene or methine compounds with alkyl halides, in an irreversible manner. The reaction mechanism illustrated above is exemplified by the asymmetric alkylation of glycine Schiff base (Scheme 1.5) [8]. 

With regards to the mechanism of the generation of onium anion, the Starks extraction mechanism and interfacial mechanism (Brandstrom-Montanari modification) are suggested (Scheme 1.7). As in the above-described case, the interfacial mechanism seems to be operative in the asymmetric phase-transfer catalysis. 

For general reviews on asymmetric phase-transfer catalysis, see (a) Shioiri, T. (1997) Handbook of Phase-Transfer Catalysis (eds Y. Sasson and R. Neumann), Blackie Academic Professional, London, Chapter 14 (b) O Donnell, M.J. (1998) Phases - The Sachem Phase Transfer Catalysis Review, (4) p. 5 (c) O Donnell, M.J. (1999) Phases - The Sachem Phase Transfer Catalysis Review, (5) p. 5 ... 

As reviewed in this chapter, cinchona alkaloids have played a crucial role in the development of asymmetric phase-transfer catalysis since its advent, and today constitute a privileged structural motif that may be widely utilized for the design of new chiral quaternary ammonium salts. These benefits are due not only to the... 

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. 

Cinchona Alkaloids in Asymmetric Phase-Transfer Catalysis... 

The phase-transfer benzylation of 2 with the catalyst (S)-12a having [1-naphthyl group on the 3,3 -position of the flexible biphenyl moiety proceeded smoothly at 0 °C to afford the corresponding alkylation product (R)-3 in 85% yield with 87% ee after 18 h. The origin of the observed chiral efficiency could be ascribed to the considerable difference in catalytic activity between the rapidly equilibrated, diaste-reomerichomo- and heterochiral catalysts namely, homochiral (S,S)-12a is primarily responsible for the efficient asymmetric phase-transfer catalysis to produce 3 with high enantiomeric excess, whereas the heterochiral (R,S)-12a displays low reactivity and stereoselectivity. 

Asymmetric phase-transfer catalysis with (S,S)-lg can be successfully extended to the stereoselective N-terminal alkylation of Gly-Ala-Phe derivative 61 (i.e., the asymmetric synthesis of tripeptides), where (S,S)-lg turned out to be a matched catalyst in the benzylation of DL-61, leading to the almost exclusive formation of DDL-62. This tendency for stereochemical communication was consistent in the phase-transfer alkylation of DDL-63, and the corresponding protected tetrapeptide DDDL-64 was obtained in 90% yield with excellent stereochemical control (94% de) (Scheme 5.30) [31]. 

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