Chirality degradation

In the later work, low optical activity (<30% ee) was observed for the products [e.g. 5] and the high asymmetric induction of the earlier work was attributed to carry over of the catalyst or chiral degradation derivatives (oxiranes) of the catalysts. Although the reported stereoselective reduction of acetophenone has been discredited, it has been suggested that the use of a chiral solvent, such as menthyl methyl ether, enhances the asymmetric reduction [7], The veracity of this claim has not been proven. 

This phenomenon of chirality degradation is carried to the extreme in the polymerization of (-F)-rrinactive polymer One of the two equivalent asymmetric atoms inverts its configuration during polymerization giving rise to a monomer unit with eiythro or meso strac-ture. The isotactic polymer, 40, so formed is clearly achiral (280). 

Figure 4.2 Structures of chiral a-HCH and its chiral degradate p-PCCH, and achiral (prochiral)...

The molecular structure imparts cellulose with its characteristic properties such as hydrophilicity, chirality, degradability, and broad chemical variability initiated by the high donor reactivity of the OH groups. It is also the basis of the extensive hydrogen bond networks, which give cellulose a multitude of partially crystalline fibre structures and morphologies. 

A variety of strategies have been devised to obtain chiral separations. Although the focus of this article is on chromatographicaHy based chiral separations, other methods include crystallisation and stereospecific ensymatic-catalysed synthesis or degradation. In crystallisation methods, racemic chiral ions are typically resolved by the addition of an optically pure counterion, thus forming diastereomeric complexes. 

Bis-(l-chloro-2-propyl)ether has two chiral centers, and exists in (R,R)-, (S,S)-, and a meso form. It is degraded by Rhodococcus sp. with a preference for the 5,5-enantiomer with the intermediate formation of l-chloro-propan-2-ol and chloroacetone (Garbe et al. 2006). 

Buser H-R, MD Muller, ME Balmer (2002) Environmental behavionr of the chiral acetamide pesticide metalaxyl enantioselective degradation and chiral stability in soil. Environ Sci Technol 36 221-226. 

Simoni S, S Klinke, C Zipper, W Angst, H-P E Kohler (1996) Enantioselective metabolism of chiral 3-phenyl-butyric acid, an intermediate of linear alkylbenzene degradation, by Rhodococcus rhodochrous. Appl... 

Zipper C, M Bunk, AJB Zehnder, H-PE Kohler (1998) Enantioselective uptake and degradation of the chiral herbicide dichloroprop [(R5)-2-(2,4-dichlorophenoxy)propionic acid] by Sphingomonas herbicidov-orans MH. J Bacteriol 180 3368-3374. 

Zipper C, K Nickel, W Angst, H-PE Kohler (1996) Complete microbial degradation of both enantiomers of the chiral herbicide Mecoprop [(R,S)-2-(4-chloro-2-methylphenoxy)]propionic acid in an enantioselective manner by Sphingomonas herbicidovorans sp. nov. Appl Environ Microbiol 62 4318-4322. 

Peptide synthesis from y9-amino acids is particularly attractive for first feasibility micro-reactor tests as there are no chiral centers which may complicate analysis of the products [5, 88]. y0-Peptides are also attractive owing to their stmctural and biological properties, especially concerning the stability versus degradation by peptidases as compared with their a-analogues (see original citations in [5]). 

Nitroalkenes with Chiral Auxiliaries The use of carbohydrates as chiral auxiliary in Diels-Alder reactions for the stereoselective preparation of carbocyclic and heterocyclic chiral rings is well documented.48 For example, D-manno-nitroalkene reacts with 2,3-dimethyl-1,3-butadiene to give a 65 35 mixture of adducts, as shown in Eq. 8.29. The configurations at C-4 and C-5 have been determined to be (4R,5R) and (45,55), respectively. Hydrolysis of the product followed by degradative oxidation of the sugar side chains leads to enantiomerically... 

These enzymes catalyze a variety of oxidative reactions in natural product biosynthesis with two C—Hhydroxylation examples shown in Figure 13.24 [72,73]. It should be noted thatC—H activation by nonheme iron oxygenases, such as aromatic dioxygenases, is an important pathway in degradation of aromatics into m-dibydrodiols, which are important chiral building blocks for chemical synthesis [74,75]. 

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