Optically active sulfoxides synthesis

This chapter, however, does not deal with above-mentioned reactions of sulfoxides. Rather it is limited to asymmetric synthesis using a-sulfinyl carbanions and -unsaturated sulfoxides, specifically in which the stereogenic sulfoxide sulfur atom is enantiomerically pure. Therefore reactions of racemic sulfoxides are for the most part excluded from this review. For more general discussions, the reader is referred to other chapters in this volume and to other reviews on the chemistry of sulfoxides. Especially useful are the reviews by Johnson and Sharp and by Mislow in the late 1960s and by Oae and by Nudelman as well as a book by Block . A review by Cinquini, Cozzi and Montanari" through mid-1983 summarizes the chemistry and stereochemistry of optically active sulfoxides. This chapter emphasizes results reported from 1984 through mid-1986. 

Optically active sulfoxides are well known and several synthetic methods have been developed, with numerous papers published on asymmetric synthesis utilizing optically active sulfoxides as chiral sources.1,6... 

Rearrangement of dienynols to vinylallene sulfoxides. A few years ago, Oka-mura et al. (11, 39) reported the rearrangement of a dienynol to an allenyldiene with transfer of chirality of the propargylic alcohol. This rearrangement has now been used for an enantioselective synthesis of a sesquiterpene, (+ )-sterpurene (3).Thus reaction of the optically active propargylic alcohol 1 with C6H,SC1 at 25° results in a vinylallene (a) that cyclizes to the optically active sulfoxide 2. Nickel-... 

The Andersen synthesis of chiral sulfoxides has also been extended to diastereomerically or enantiomerically pure arenesulfinamides, which on treatment with methyllithium give optically active methyl aryl sulfoxides (83,85). The use of menthyl sulfinates in the synthesis of sulfoxides has been exploited in the preparation of optically active sulfoxides 47 and 48, which are chiral by virtue of isotopic substitution, H- D (86), and (87), respectively. More recent... 

Enantiomerically pure sulfoxides play an important role in asymmetric synthesis either as chiral building blocks or stereodirecting groups [156]. In the last years, metal- and enzyme-catalyzed asymmetric sulfoxidations have been developed for the preparation of optically active sulfoxides. Among the metal-catalyzed processes, the Kagan sulfoxidation [157] is the most efficient, in which the sulfide is enantioselectively oxidized by Ti(OzPr)4/tBuOOH in the presence of tartrate as chirality source. However, only alkyl aryl sulfides may be oxidized by this system in high enantiomeric excesses, and poor enantioselectivities were observed for dialkyl sulfides. 

This procedure was extended to a method for asymmetric synthesis of optically active epoxides starting from optically active sulfoxides. As the oxiranyUithium 131 reacts with the acidic hydrogen of the n-butyl aryl sulfoxide, the introduction of electrophiles to the reaction mixture was problematic. Therefore, the reaction was performed by addition of 1 equivalent of f-C4H9Li at — 100°C to 130 and the sulfoxide-lithium exchange reaction was found to be extremely rapid (within a few seconds at this temperature). Moreover, as f-butyl aryl sulfoxide 138 has now no more acidic hydrogen, the addition of several electrophiles leads to functionalized epoxides 139 (equation 48). ... 

The asymmetric oxidation of prochiral sulfides has become the method of choice for the synthesis of optically active sulfoxides. The first examples of a really efficient asymmetric oxidation of snlfides to sulfoxides were independently reported by Pitchen... 

It is not the purpose of this section to discuss the synthesis of optically active sulfoxides which have recently been reviewed9. However, it is important to add recent results describing more efficient ways to introduce a chiral sulfoxide group in a molecule. 

Chiral sulfoxides have emerged as versatile building blocks and chiral auxiliaries in the asymmetric synthesis of pharmaceutical products. The asymmetric oxidation of prochiral sulfides with chiral metal complexes has become one of the most effective routes to obtain these chiral sulfoxides.We have recently developed a new heterogeneous catalytic system (WO3-30% H2O2) which efficiently catalyzes both the asymmetric oxidation of a variety of thioethers (1) and the kinetic resolution of racemic sulfoxides (3), when used in the presence of cinchona alkaloids such as hydroquinidine 2,5-diphenyl-4,6-pyrimidinediyl diether [(DHQD)2-PYR], Optically active sulfoxides (2) are produced in high yields and with good enantioselectivities (Figure 9.3). ... 

Table 23. Synthesis of Optically Active Sulfoxides, MeS(0)R, from DAG Methanesulfinates and R MgX...

SYNTHESIS OF OPTICALLY ACTIVE SULFOXIDES AND SELENOXIDES BY CHEMICAL AND BIOLOGICAL OXIDATION... 

Synthesis of Optically Active Sulfoxides by Chemical Oxidation... 

Preparation of Chiral Sulfinates. Optically active sulfinates can be prepared by reaction of a symmetrical sulfite with t-Butylmagnesium Chloride in the presence of an optically active amino alcohol. The best enantioselectivity has been observed using quinine as the optically active amine (eq 2)3 An alternative approach to this new enantioselective asymmetric synthesis of alkyl t-butylsulfinates would be reaction of a racemic sulfinate with r-butylmagnesium chloride complexed by optically active alkaloids (eq 3). In this case, kinetic resolution of the racemic sulfinate leads to an optically active sulfinate and an optically active sulfoxide. 

The use of optically active sulfoxides for the synthesis of optically active alkenes has been reported, e.g. the (5)-sulfoxide (55) gave the (5)-alkene (56) on heating at 250 C (equation 27). However, the observed enantiomeric excesses were only modest and the reactions were only carried out to low conversions. 

Oxidation of unsymmetrical sulfides, such as 125, to the corresponding optically active sulfoxides with CBT is high enantioselective, for example, in the synthesis of (S)-(-)-BOF-4272 126a, a xantine dehydrogenase inhibitor. Reaction proceeds in DMF in the presence of 4-cyanopyridine and a chiral alcohol (96TA2991) (Scheme 122). 

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