Organic chemistry chirality

In organic chemistry chirality most often occurs m molecules that contain a car bon that is attached to four different groups An example is bromochlorofluoromethane (BrClFCH)... 

The metal centre. In organic chemistry, chiral centres are usually associated with an asymmetric carbon atom, but this notion is of limited use for metal ions. Most tetrahedral metal ions are extremely labile, although pseudo-tetrahedral complexes such as (C5H5)MLL L" may be resolved into enantiomers. Octahedral centres with... 

Since oxazolidines and oxazolidinones are fiindamental structural classes in organic chemistry (chiral auxiliaries) and in medicinal chemistry (e.g., Linezolid) and since they mask P-hydroxy-a-amino acids, which are widespread in various biologically active compounds and in natural products, the enantioselective synthesis of oxazolidinones is a challenging topic. Indeed, a new method for the direct synthesis of chiral 4-carboxyl oxazolidinones 168 by the catalytic asymmetric aldol reaction of isocyanato-malonate diesters 166 with aldehydes 167 in the presence of a thiourea catalyst (TUC) was developed. Since the resulting chiral 4-carboxy oxazolidinones are the equivalent of P-hydroxy-a-amino acids, this procedure... 

CILs are a subclass of ILs in which the cation or the anion (or both) may be chiral. The chirality can be either central, axial, or planar. It is well established that chirality plays an important role in chemistry. Over the last few years, research for new chiral selectors, solvents, and materials based on CILs has become a topic of increasing interest. A growing number of CILs have been designed, synthesized, and utilized for potential applications in chiral discrimination and separation [24], asymmetric catalysis and synthesis [25], as well as optical resolution of racemates [26]. Because of their high-resolution abilities and liquidus properties, CILs can be used as either chiral agents in regular solvent, or chiral solvents, or both simultaneously. With the rapid development of CILs, these new chiral solvents have the potential to play an important role in enantioselective organic chemistry, chiral separation chemistry, and chiral materials chemistry. Thus, their role in these fields is expected to expand tremendously. 

In organic chemistry there are many important molecules that contain two or more groups each of which, in isolation, would be chiral. A simple example is that of 2,3-difluorobutane, shown in Figure 4.9. The molecule can be regarded as a substituted ethane and we assume that, as in ethane itself, the stable sttucture is one in which one CFIFCFI3 group is staggered relative to the other. 

In Chapter 4, on molecular symmetry, 1 have added two new sections. One of these concerns the relationship between symmetry and chirality, which is of great importance in synthetic organic chemistry. The other relates to the connection between the symmetry of a molecule and whether it has a permanent dipole moment. 

Although many carbonyl derivatives act as acyl cation equivalents, R(C=0)" in synthetic chemistry, the inherent polarity of the carbonyl group makes it much more difficult to find compounds that will act as equivalents of acyl anions, R(C=0) . Since the 1960s, major progress has been made in this area, and there are now a wide variety of compound types that can react in this way. As in so many areas of organic chemistry, heterocyclic compounds take pride of place and form the basis of many of the most useful methods. In recent years there has been particular interest in developing chiral acyl anion equivalents that will show high... 

The [ 2 + 4]-cycloaddition reaction of aldehydes and ketones with 1,3-dienes is a well-established synthetic procedure for the preparation of dihydropyrans which are attractive substrates for the synthesis of carbohydrates and other natural products [2]. Carbonyl compounds are usually of limited reactivity in cycloaddition reactions with dienes, because only electron-deficient carbonyl groups, as in glyoxy-lates, chloral, ketomalonate, 1,2,3-triketones, and related compounds, react with dienes which have electron-donating groups. The use of Lewis acids as catalysts for cycloaddition reactions of carbonyl compounds has, however, led to a new era for this class of reactions in synthetic organic chemistry. In particular, the application of chiral Lewis acid catalysts has provided new opportunities for enantioselec-tive cycloadditions of carbonyl compounds. 

Asymmetric synthesis is a stimulating academic challenge, but since it has become clear that most chiral drugs can be administered safely only in the enantiomerically pure form, the industrial need for asymmetric methods has made research in asymmetric synthesis absolutely necessary [5]. This has driven a renaissance in the discipline of organic chemistry, because all of the old-established reactions need to be reinvestigated for their application in asymmetric synthesis [6]. This has also applied... 

The strategy described here explains the different possibilities of enzymatic ammonolysis and aminolysis reaction for resolution of esters or preparation of enantiomerically pure amides, which are important synthons in organic chemistry. This methodology has been also applied for the synthesis of pyrrolidinol derivatives that can be prepared via enzymatic ammonolysis of a polyfunctional ester, such as ethyl ( )-4-chloro-3-hydroxybutanoate [30]. In addition, it is possible in the resolution of chiral axe instead of a stereogenic carbon atom. An interesting enzymatic aminolysis of this class of reaction has been recently reported by Aoyagi et al. [31[. The side chain of binaphthyl moiety plays an important role in the enantiodis-crimination of the process (Scheme 7.14). 

Metal-assisted enantioselective catalytic reactions are one of the most important areas in organic chemistry [1-3]. They require the appropriate design and the preparation of chiral transition metal complexes, a field also of major importance in modern synthetic chemistry. These complexes are selected on both their ability to catalyze a given reaction and their potential as asymmetric inducers. To fulfill the first function, it is absolutely required that the catalysts display accessible metal coordination sites where reactants can bind since activation would result from a direct interaction between the metal ion... 

As in organic chemistry, there are several sources of chirality at a metal center. As for an asymmetric carbon atom in an organic molecule, the coordination of the metal ion by four different monodentate hgands in a tetrahedral con-... 

In many cases, the racemization of a substrate required for DKR is difficult As an example, the production of optically pure cc-amino acids, which are used as intermediates for pharmaceuticals, cosmetics, and as chiral synfhons in organic chemistry [31], may be discussed. One of the important methods of the synthesis of amino acids is the hydrolysis of the appropriate hydantoins. Racemic 5-substituted hydantoins 15 are easily available from aldehydes using a commonly known synthetic procedure (Scheme 5.10) [32]. In the next step, they are enantioselectively hydrolyzed by d- or L-specific hydantoinase and the resulting N-carbamoyl amino acids 16 are hydrolyzed to optically pure a-amino acid 17 by other enzymes, namely, L- or D-specific carbamoylase. This process was introduced in the 1970s for the production of L-amino acids 17 [33]. For many substrates, the racemization process is too slow and in order to increase its rate enzymes called racemases are used. In processes the three enzymes, racemase, hydantoinase, and carbamoylase, can be used simultaneously this enables the production of a-amino acids without isolation of intermediates and increases the yield and productivity. Unfortunately, the commercial application of this process is limited because it is based on L-selective hydantoin-hydrolyzing enzymes [34, 35]. For production of D-amino acid the enzymes of opposite stereoselectivity are required. A recent study indicates that the inversion of enantioselectivity of hydantoinase, the key enzyme in the... 

In this work a new approach is desribed, which can help to understand ED over heterogeneous catalysts We also hope that this approach can be used to find new modifiers for enantioselective heterogeneous catalytic reactions. The basis for this approach is the steric shielding known in organic chemistry [7,8]. A chiral template molecule can induce shielding effect (SE) in such a way that it preferentially interacts with one of the prochiral sites of the substrate. If a substrate is preferentially shielded its further reaction can take place only fi"om its unshielded site resulting in ED. 

Choudary, B.M., Chowdari, N.S., Mahdi, S., Kantam, M.L. (2003) A Trifimctional Catalyst for One-Pot Synthesis of Chiral Diols via Heck Coupling-N-Oxidation-Asymmetric Dihydroxyla-tion Application for the Synthesis of Diltiazem and Taxol Side Chain. Journal of Organic Chemistry, 6S, 1736-1746. 

Aoyagi, S., Tanaka, R., Naruse, M., Kibayashi, C. (1998) Total Synthesis of (—)-Epibatidine Using an Asymmetric Diels-Alder Reaction with a Chiral N-Acylnitroso DienophUe. Journal of Organic Chemistry, 63, 8397-8406. 

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. 

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