Organic reactions enantioselective

To our knowledge, the results presented in this chapter provide the first example of enantioselective Lewis-acid catalysis of an organic reaction in water. This discovery opens the possibility of employing the knowledge and techniques from aqueous coordination chemistry in enantioselective catalysis. This work represents an interface of two disciplines hitherto not strongly connected. 

Of all the work described in this thesis, this discovery is probably the most significant. Given the fact that the arene - arene interactions underlying the observed enantioselectivity of ftie Diels-Alder reactions described in Chapter 3 are also encountered in other organic reactions, we infer that, in the near future, the beneficial influence of water on enantioselectivity can also be extended to these transformations. Moreover, the fact that water can now be used as a solvent for enantioselective Lewis-add catalysed reactions facilitates mechanistic studies of these processes, because the number of equilibria that need to be considered is reduced Furthermore, knowledge and techniques from aqueous coordination chemistry can now be used directly in enantioselective catalysis. 

Also the arene-arene interactions, as encountered in Chapter 3, are partly due to hydrophobic effects, which can be ranked among enforced hydrophobic interactions. Simultaneous coordination of an aromatic oc amino acid ligand and the dienophile to the central copper(II) ion offers the possibility of a reduction of the number of water molecules involved in hydrophobic hydration, leading to a strengthening of the arene-arene interaction. Hence, hydrophobic effects can have a beneficial influence on the enantioselectivity of organic reactions. This effect is anticipated to extend well beyond the Diels-Alder reaction. 

Here, the temperature effect is discussed from the aspect of synthetic utility. Temperature control of enantioselectivity, i.e., the low-temperature method , is simple and now practically acceptable method. The phenomenon is based on the theory of physical organic chemistry and will be studied further for understanding the enzymatic reaction as organic reaction. 

The focus of Part B is on the closely interrelated topics of reactions and synthesis. In each of the first twelve chapters, we consider a group of related reactions that have been chosen for discussion primarily on the basis of their usefulness in synthesis. For each reaction we present an outline of the mechanism, its regio- and stereochemical characteristics, and information on typical reaction conditions. For the more commonly used reactions, the schemes contain several examples, which may include examples of the reaction in relatively simple molecules and in more complex structures. The goal of these chapters is to develop a fundamental base of knowledge about organic reactions in the context of synthesis. We want to be able to answer questions such as What transformation does a reaction achieve What is the mechanism of the reaction What reagents and reaction conditions are typically used What substances can catalyze the reaction How sensitive is the reaction to other functional groups and the steric environment What factors control the stereoselectivity of the reaction Under what conditions is the reaction enantioselective ... 

Cyanohydrination (addition of a cyano group to an aldehyde or ketone) is another classic reaction in organic synthesis. Enantioselective addition of TMSCN to aldehyde, catalyzed by chiral metal complexes, has also been an active area of research for more than a decade. The first successful synthesis using an (5,)-binaphthol based complex came from Reetz s group142 in 1986. Their best result, involving Ti complex, gave 82% ee. Better results were reported shortly thereafter by Narasaka and co-workers.143 They showed that by... 

F. Spindler, B. Pugin, H.-P. Jalett, H.-P. Buser, U. Pittelkow, H.-U Blaser, A Technically Useful Catalyst for the Homogeneous Enantioselective Hydrogenation of N-Aryl Imines A Case Study, in Catalysis of Organic Reactions (Ed. R. E. Maltz), Dekker, New York, 1996, pp. 153-168. 

Among the various methods proposed to produce selectively isolated enantiomers, the use of enantioselective catalysis is by far the most attractive one. The control of stereochemistry by use of a minute amount of an asymmetric catalyst offers clear advantages. Therefore, the design and development of catalytic enantioselective organic reactions is considered as one of the most attractive and challenging frontiers in synthetic organic chemistry. 

A more versatile method to use organic polymers in enantioselective catalysis is to employ these as catalytic supports for chiral ligands. This approach has been primarily applied in reactions as asymmetric hydrogenation of prochiral alkenes, asymmetric reduction of ketone and 1,2-additions to carbonyl groups. Later work has included additional studies dealing with Lewis acid-catalyzed Diels-Alder reactions, asymmetric epoxidation, and asymmetric dihydroxylation reactions. Enantioselective catalysis using polymer-supported catalysts is covered rather recently in a review by Bergbreiter [257],... 

Carbon-carbon bond-forming reactions are one of the most basic, but important, transformations in organic chemistry. In addition to conventional organic reactions, the use of transition metal-catalyzed reactions to construct new carbon-carbon bonds has also been a topic of great interest. Such transformations to create chiral molecules enantioselectively is therefore very valuable. While various carbon-carbon bond-forming asymmetric catalyses have been described in the literature, this chapter focuses mainly on the asymmetric 1,4-addition reactions under copper or rhodium catalysis and on the asymmetric cross-coupling reactions catalyzed by nickel or palladium complexes. 

Esters are widespread in fruits and especially those with a relatively low molecular weight usually impart a characteristic fruity note to many foods, e.g. fermented beverages [49]. From the industrial viewpoint, esterases and lipases play an important role in synthetic chemistry, especially for stereoselective ester formations and kinetic resolutions of racemic alcohols [78]. These enzymes are very often easily available as cheap bulk reagents and usually remain active in organic reaction media. Therefore they are the preferred biocatalysts for the production of natural flavour esters, e.g. from short-chain aliphatic and terpenyl alcohols [7, 8], but also to provide enantiopure novel flavour and fragrance compounds for analytical and sensory evaluation purposes [12]. Enantioselectivity is an impor-... 

The conversion of co-hydroxyalkanals to the corresponding cyanohydrins in moderate enantioselectivities could also be accomplished by transhydrocyanation with acetone cyanohydrin as the cyanide source. These substrates are considered difficult because of their high solubility in water. Through the employment of an almond meal preparation in a micro-aqueous organic reaction system, the ee-values could be significantly improved [54]. 

Continuing the theme of small molecules as catalysts for organic reactions, Eric Jacobsen of Harvard has reported (J. Am. Chem. Soc. 2004,126, 10558) the design of a peptide thiourea that mediates enantioselective Pictet-Spengler cyclization, e.g. of 1 to 2. 

T. Hayashi and M. Kumada, Asymmetric Coupling Reactions, in J. D. Morrison, ed., Asymmetric Synthesis, Vol. 5, Chap. 5, Academic Press, New York, 1985 J. C. Fiaud, Mechanisms in Stereo-Differentiating Metal-Catalyzed Reactions. Enantioselective Palladium-Catalyzed Allylation, in A. F. Noels, M. Graziani, and A. J. Hubert, eds., Metal Promoted Selectivity in Organic Synthesis, p. 107, Kluwer Academic, Dordrecht, 1991. 

Scheme 3 illustrates intriguing enantioselection in organic reactions that proceed in chiral crystalline lattices (5). When inclusion crystals of a ketone and an optically active diol host are treated with BH3-ethyl-enediamine complex, the optically active alcohol is obtained in... 

Recent editions of Organic Reaction Mechanisms have highlighted a number of carbene and nitrene CH-insertion reactions. This field has now been reviewed with a focus on enantioselective reactions catalysed typically by dirhodium species.5 The use of C2-symmetric box ligands in asymmetric cyclopropanation reactions has been discussed in the context of a wider review of these ligands as a source of asymmetry.6... 

Biocatalysts, mainly hydrolytic enzymes and oxidoreductases, have been used for organic reactions due to their excellent enantioselectivities and environmentally friendliness.1 Typical enzymatic reactions used for the organic synthesis are shown in Figure 1. Especially, hydrolytic enzymes for kinetic resolutions of racemates have been utilized widely because of their high stabilities, wide substrate specificities, lack of cofactor requirements and high availabilities. 

A range of chiral pre-organized diols have been studied to assess their potential to catalyse vinylogous Mukaiyama aldol reactions enantioselectively via hydrogen bonds.141... 

Due to high efficiency and in some cases even enantioselectivity, solid state reactions have recently attracted considerable attention to various types of organic reactions [194-197]. The solid-state Michael reactions between 4-arylidene-3-methyl-l-phenyl-5-pyrazolones 267a-f and indole gave rea-... 

Over the past half-dozen years, many laboratories have focused their efforts on the development of chiral hydrogen bond donors that function as catalysts for enantioselective organic reactions. One of the earliest successes in this area came from Jacobsen and co-workers, who reported the use of peptide-like chiral urea-based catalysts for the hydrocyanation of aldimines and ketoimines [40, 41]. Several other laboratories have also reported highly enantioselective transformations catalyzed by a chiral hydrogen bond donor. The following sections provide a summary of the many developments in hydrogen bond-catalyzed enantioselective reactions, along with a discussion of mechanisms and selectivity models. 

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