Sulfoxides, chiral

The development of the single enantiomer azole within the family of compounds used for gastrointestinal treatments is exemplified by Astra-Zeneca s Esomeprazole (a potent gastric acid secretion inhibitor) (Eigure 1.54). This development gave the impetus for the search for industrial chiral sulfoxidation catalysts. 

The development of a large scale manufacturing route to Esomeprazole is described by Federsel and Larsson ° using the titanium catalyst originally described by Kagan and Luukas. Employment of a tartaric acid derived chiral auxiliary, with the addition of a base such as diisopropylethylamine to the reaction mixture, resulted in a full-scale catalytic process capable of delivering multi-ton quantities of product with optical yields well above 90 %, a figure which could be raised to 99.5 % ee by recrystallization from methyl isobutyl ketone. 

These reactions may give very high enantioselectivities, particularly for structures such as ArS(0)Me and this approach has been used on a multi-kilogram scale in industry. 

Blaser, H.U. and Schmidt, E. (Eds) Asymmetric Catalysis on Industrial Scale. Wiley-VCH Weinheim, 2004. 

Kuwano, R. and Kashiwahara, M. Ruthenium-catalyzed Asymmetric Hydrogenation of N-Boc-Indoles. Org. Lett. 2006, 8, 2653-2655. 

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The large sulfur atom is a preferred reaction site in synthetic intermediates to introduce chirality into a carbon compound. Thermal equilibrations of chiral sulfoxides are slow, and parbanions with lithium or sodium as counterions on a chiral carbon atom adjacent to a sulfoxide group maintain their chirality. The benzylic proton of chiral sulfoxides is removed stereoselectively by strong bases. The largest groups prefer the anti conformation, e.g. phenyl and oxygen in the first example, phenyl and rert-butyl in the second. Deprotonation occurs at the methylene group on the least hindered site adjacent to the unshared electron pair of the sulfur atom (R.R. Fraser, 1972 F. Montanari, 1975). 

New reactions utilizing features of sulfur atom in chiral sulfoxides, derivatives of heterocycles 99YZ126. 

Remote asymmetric induction using chiral sulfoxides, derivatives of furan, thiophene, and pyrrole 98YGK798. 

A chiral sulfoxide can be used as a leaving group for the asymmetric inducdon via addidon-eliminadonprocess. 5-Lactam enolates are converted into the corresponding nitroalkenes subsdnited with lactams fEq. 4.101. ... 

High diastereoselectivity at the sulfinyl group bearing carbon and low diastereoselectivity at the prostereogenic carbonyl group resulted on addition of a chiral sulfoxide carbanion to an... 

The big difference between the extent of asymmetric induction on the addition to a prostereogenic carbonyl group of simple carbanions a to a chiral sulfoxide on the one hand and enolates of sulfinyl esters on the other, can be attributed to the capacity of the ester function to chelate magnesium in the transition states and intermediates. The results already described for the addition of chiral thioacetal monosulfoxide to aldehydes (see Section 1.3.6.5.) underscore the importance of other functions, e.g., sulfide, for the extent of asymmetric induction. 

Chiral sulfoxides with at least one sulfur-bonded aryl group have been separated by liquid chromatography into the enantiomers26. Some of the columns employed, which are commercially available, used 3,5-dinitrobenzoyl)phenylglycine bonded to silica... 

In order to account for the unusually facile thermal racemization of optically active allyl p-tolyl sulfoxide (15 R = p-Tol) whose rate of racemization is orders of magnitude faster than that of alkyl aryl or diaryl sulfoxides as a result of a comparably drastically reduced AH (22kcalmol- ), Mislow and coworkers44 suggested a cyclic (intramolecular) mechanism in which the chiral sulfoxide is in mobile equilibrium with the corresponding achiral sulfenate (equation 10). 

Several alkyl aryl sulfides were electrochemically oxidized into the corresponding chiral sulfoxides using poly(amino acid)-coated electrodes448. Although the levels of enan-tioselection were quite variable, the best result involved t-butyl phenyl sulfoxide which was formed in 93% e.e. on a platinum electrode doubly coated with polypyrrole and poly(L-valine). Cyclodextrin-mediated m-chloroperbenzoic acid oxidation of sulfides proceeds with modest enantioselectivity44b. 

Enzyme-mediated chiral sulfoxidation has been reviewed comprehensively in historical context [188-191]. The biotransformation can be mediated by cytochrome P-450 and flavin-dependent MOs, peroxidases, and haloperoxidases. Owing to limited stability and troublesome protein isolation, a majority of biotransformations were reported using whole-cells or crude preparations. In particular, fungi have been identified as valuable sources of such biocatalysts and the catalytic entities have not been fully identified in all cases. 

Scheme 9.26 Oxygenation of sulfides to chiral sulfoxides and nonchiral sulfones.

Sulfoxidations are not restricted to MOs but can also be carried out by dioxygenases. For example. Pseudomonas mutant strain UV4 producing a toluene dioxygenase (TOO) and Pseudomonas NCIMB 8859 expressing a naphthalene dioxygenase (NDO) were used to oxidize aryl sulfides to antipodal chiral sulfoxides [203]. 

Within the biooxidation of disulfides, chiral thiosulfinates become available. Tert-Butyl tert-butanethiosulfinate represents a particularly valuable chiral auxiliary for the preparation of several chiral sulfoxides and sulfinimines, which can be subsequently transformed into branched amine compounds, P-aminoacids, and chiral aziridines. This product is accessible readily by mediated biooxidation of tert-butyl... 

For a review of the synthetic uses of 3-keto sulfoxides, sulfones, and sulfides, see Trost, B.M. Chem. Rev., 1978, 78, 363. For a review of asymmetric synthesis with chiral sulfoxides, see Solladie, G. Synthesis, 1981, 185. 

If the reagent is optically active because of the presence of a chiral sulfoxide group, the reaction can be enantioselective. For a review of such cases, see Solladie, G. Chimia, 1984, 38, 233. 

Holland HE (1988) Chiral sulfoxidation by biotransformation of organic sulfides. Chem Rev 88 473-485. 

ABSTRACT Zeolite Y modified with chiral sulfoxides has been foimd catal rtically to dehydrate racemic butan-2-ol enantioselectively depending on the chiral modifier used. Zeolite Y modified with R-l,3-dithiane-1-oxide shows a higher selectivity towards conversion of S-butan-2-ol and the zeolite modified with S-2-phenyl-3-dithiane-1-oxide reacts preferentially with R-butan-2-ol. Zeolite Y modified with dithiane oxide demonstrates a significantly higher catalsdic activity when compared to the unmodified zeolite. Computational simulations are described and a model for the catalytic site is discussed. 

In a further set of experiments racemic butan-2-ol was reacted with zeolite Y modified with chiral sulfoxides. In the first set of experiments racemic butan-... 

Marino, J.P., Bogdan, S., Kimura, K. (1992) The Enantioselective Synthesis of (—)-Physostigmine via Chiral Sulfoxides. Journal of the American Chemical Society, 114, 5566-5572. 

In 2005, Nguyen et al. reported the first example of asymmetric cyclopropa-nation of olefins with EDA mediated by a combination of a (salen) ruthenium(II) catalyst and a catalytic amount of a chiral sulfoxide (Scheme 6.7). These authors proposed that the mechanism explaining the asymmetric induction involved the axial coordination of the chiral sulfoxide to the ruthenium centre as the key induction step in the reaction stereoselectivity. 

On the other hand, James reported, in 1976, the use of a chiral sulfoxide as a ligand of ruthenium for the asymmetric hydrogenation of itaconic acid, providing a low enantioselectivity of 12% ee (Scheme 8.23). ... 

The first use of chiral sulfoxides as Lewis-base catalysts in the allylation of aldehydes with allyltrichlorosilane was reported in 2003. The formation of the... 

Moreover, Kobayashi et al. introduced chiral sulfoxides into the reactions of A -acylhydrazones with allyltrichlorosilanes as highly elBcient neutral coordi-nating-organocatalysts (Scheme 10.23)." The corresponding chiral homoallylic... 

In addition, Rowlands has involved chiral sulfoxide-containing ligands for the catalytic addition of McsSiCN to aldehydes. " The ligand structure was based on a phenolic oxazoline scaffold with introduction of the sulfur substituent via cysteine derivatives. The best enantioselectivities of up to 61% ee were obtained with the bulkiest tert-butyl substituted ligand (Scheme 10.42). The effect of the sulfoxide configuration was studied, showing that the use of... 

Except for the syntheses using terpene-derived starting materials (Schemes 13.7, 13.8, and 13.9), the previous juvabione syntheses all gave racemic products. Some of the more recent juvabione syntheses are enantiospecific. The synthesis in Scheme 13.16 relied on a chiral sulfoxide that undergoes stereoselective addition to cyclohexenone to establish the correct relative and absolute configuration at C(4) and C(7). The origin of the stereoselectivity is a chelated TS that leads to the observed product.20... 

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