Chiral racemization

Q Chiral racemic y-alkyl-substituted enones the titanium(IV) chloride mediated addition of enol silanes and silylketene acetals to 7 shows high induced diastereoselection (diastereomeric ratios from 89 11 to more than 97 3) and the major isomer 8 results from addition of the enolsilane with ul topicity288. Re face attack on the S enantiomer of 7.)... 

The purpose of the present chapter is to provide an up-to-date review of methods which may be applied for the synthesis of both achiral and chiral (racemic and optically active) sulphoxides as well as their derivatives. Since the synthesis of optically active sulphoxides is based on many special procedures, it was found necessary to separate the syntheses of achiral and racemic sulphoxides from those of optically active ones. 

The cycloaddition of chiral, racemic and non-racemic alkoxybutadienes 109 with phenyltriazolinedione led to aza compounds [110] in high yield, with good facial selectivity (diastereomeric excess 87-92%) (Equation 2.31). The cycloadditions of the same dienes with N-phenylmaleimide require Lewis acid catalysis. 

C-chiral racemic y-hydroxy sulfides were also resolved using PEL under kinetic resolution conditions. The products were transformed into optically active 3-(alkanesulfonyloxy)thiolane salts (Scheme 1). Similarly, 1,2-cyclic sulfite glycerol derivatives cis and trans) were resolved into enantiomers via a Pseudomonas cepacia-catalysed acylation with vinyl butyrate. The E values depended on the solvent used and varied from 2 to 26. ... 

Scheme 15. Trost s approach to aflatoxin B involves the Pd-catalyzed dynamic asymmetric transformation of chiral racemic 103 to optically pure 104 (1999).

Table 9.61 Dynamic kinetic protonation of chiral racemic allenylsamarium intermediates.

Carpentier J-F (2010) Discrete metal catalysts for stereoselective rmg-openmg polymerization of chiral racemic [l-lactones. Macromol Rapid Commun 31 1696-1705... 

Hoft reported about the kinetic resolution of THPO (16b) by acylation catalyzed by different lipases (equation 12) °. Using lipases from Pseudomonas fluorescens, only low ee values were obtained even at high conversions of the hydroperoxide (best result after 96 hours with lipase PS conversion of 83% and ee of 37%). Better results were achieved by the same authors using pancreatin as a catalyst. With this lipase an ee of 96% could be obtained but only at high conversions (85%), so that the enantiomerically enriched (5 )-16b was isolated in poor yields (<20%). Unfortunately, this procedure was limited to secondary hydroperoxides. With tertiary 1-methyl-1-phenylpropyl hydroperoxide (17a) or 1-cyclohexyl-1-phenylethyl hydroperoxide (17b) no reaction was observed. The kinetic resolution of racemic hydroperoxides can also be achieved by chloroperoxidase (CPO) or Coprinus peroxidase (CiP) catalyzed enantioselective sulfoxidation of prochiral sulfides 22 with a racemic mixmre of chiral hydroperoxides. In 1992, Wong and coworkers and later Hoft and coworkers in 1995 ° investigated the CPO-catalyzed sulfoxidation with several chiral racemic hydroperoxides while the CiP-catalyzed kinetic resolution of phenylethyl hydroperoxide 16a was reported by Adam and coworkers (equation 13). The results are summarized in Table 4. 

The problems of configurational assignment are principally the same for the cases discussed in Sections 4.3.3.2.2. (Formation of Chiral, Racemic Products) and 4.3.3.2.3.1. [Formation of Nonracemic Products with Known Configuration at (at least) One Chiral Unit]. This can be illustrated by the example of the conjugate addition of a methyl group to a chromone (9 on p 411) which has been performed both with racemic and with enantiomerically pure material. Thus the (relative) configuration of the reaction products was determined making use of both the racemic and the nonracemic series (see pp 472 and 480)108. 

Even in the double alkylation of chiral (racemic) 4-fert-butylcyclohexanone imine28, the ster-ically hindered c -l,3-diaxial derivative is formed selectively, followed by epimerization to the more favorable 1,3-trans-product 2. 

With chiral racemic oxiranes one enantiomer reacts faster than the other the degree of kinetic resolution is very high for L-valine/alanine-based dialkoxydihydropyrazines. For example, in the reaction of one equivalent of (2.S )-2,5-dihydro-2-isopropyl-3,6-dimethoxy-5-methyl-pyrazine (1, R1 = CH3) with two equivalents of fW-(//,/ )-2,3-dimethyloxirane (R2,R4 = CH3 R = H) virtually only the (2//,3/ )-oxirane enantiomer reacts with the lithiated dihydropyrazine to give exclusively the (l /, 2/, 2 / )-configuratcd adduct i.e., (2/ ,5S)-2,5-dihydro-5-isopropyl-3,6-dimethoxy-2-[(l/ ,2/ )-2-(2-methoxyethoxymethoxy)-l-methylpropyl]-2-methylpyrazine, entry 7. Likewise, kinetic resolution (intramolecular) occurs upon reaction with rac-7-oxabicy-clo[4.1.0]heptane (entry 8). 

Several chiral racemic alkylamines have been successfully resolved using hydrolase-catalyzed acylation reactions with esters as acyl donors. A few examples are described here (Table 4.2). 

Chiral racemic esters can of course be resolved by hydrolase-catalyzed, hydrolytic reactions in aqueous media, which are not treated here. Alcoholysis provides an alternative. Some examples are shown in Scheme 4.43. Thus, the racemic gastro-lactyl acetate rac-149 can be efficiently resolved to give (+)-149 and the lactol 150 by butanolysis catalyzed by Amano I, PS-C [144]. The enantiopure lactol product... 

Most work on this subject is based on the use of alcohols as reagents in the presence of enantiomerically pure nucleophilic catalysts [1, 2]. This section is subdivided into four parts on the basis of classes of anhydride substrate and types of reaction performed (Scheme 13.1) - desymmetrization of prochiral cyclic anhydrides (Section 13.1.1) kinetic resolution of chiral, racemic anhydrides (Section 13.1.2) parallel kinetic resolution of chiral, racemic anhydrides (Section 13.1.3) and dynamic kinetic resolution of racemic anhydrides (Section 13.1.4). 

Kinetic resolution of chiral, racemic anhydrides In this process the racemic mixture of a chiral anhydride is exposed to the alcohol nucleophile in the presence of a chiral catalyst such as A (Scheme 13.2, middle). Under these conditions, one substrate enantiomer is converted to a mono-ester whereas the other remains unchanged. Application of catalyst B (usually the enantiomer or a pseudo-enantiomer of A) results in transformation/non-transformation of the enantiomeric starting anhydride ). As usual for kinetic resolution, substrate conversion/product yield(s) are intrinsically limited to a maximum of 50%. For normal anhydrides (X = CR2), both carbonyl groups can engage in ester formation, and the product formulas in Scheme 13.1 are drawn arbitrarily. This section also covers the catalytic asymmetric alcoholysis of a-hydroxy acid O-carboxy anhydrides (X = O) and of a-amino acid N-carboxy anhydrides (X = NR). In these reactions the electrophilicity of the carbonyl groups flanking X is reduced and regioselective attack of the alcohol nucleophile on the other carbonyl function results. 

Parallel kinetic resolution of chiral, racemic anhydrides The term parallel kinetic resolution (PKR) implies that the two substrate enantiomers (Scheme 13.1, bottom... 

Parallel kinetic resolution of chiral, racemic anhydrides ... 

Parallel Kinetic Resolution of Chiral, Racemic Anhydrides... 

Complexes of unsymmetrically substituted conjugated dienes are chiral. Racemic planar chiral complexes are separated into their enantiomers 84 and 85 by chiral HPLC on commercially available /f-cyclodextrin columns and used for enantioseletive synthesis [25]. Kinetic resolution was observed during the reaction of the meso-type complex 86 with the optically pure allylboronate 87 [26], The (2R) isomer reacted much faster with 87 to give the diastereomer 88 with 98% ee. The complex 88 was converted to 89 by the reaction of meldrum acid. Stereoselective Michael addition of vinylmagnesium bromide to 89 from the opposite side of the coordinated Fe afforded 90, which was converted to 91 by acetylation of the 8-OH group and displacement with EtjAl. Finally, asymmetric synthesis of the partial structure 92 of ikarugamycin was achieved [27],... 

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