Sulfoxides, stereoselective synthesis asymmetric

This compilation embraces a wide variety of subjects, such as solid-phase and microwave stereoselective synthesis asymmetric phase-transfer asymmetric catalysis and application of chiral auxiliaries and microreactor technology stereoselective reduction and oxidation methods stereoselective additions cyclizations metatheses and different types of rearrangements asymmetric transition-metal-catalyzed, organocatalyzed, and biocatalytic reactions methods for the formation of carbon-heteroatom and heteroatom-heteroatom bonds like asymmetric hydroamina-tion and reductive amination, carboamination and alkylative cyclization, cycloadditions with carbon-heteroatom bond formation, and stereoselective halogenations and methods for the formation of carbon-sulfur and carbon-phosphorus bonds, asymmetric sulfoxidation, and so on. 

Bravo and co-workers report asymmetric syntheses of fluoroalkylamino compoimds via chiral sulfoxides and the stereoselective synthesis of p-fluoroalkyl-p-amino alcohol units using chiral sulfoxides and the Evans aldol reaction. Begde and colleagues discuss the stereoselective and enantioselective synthesis of trifluoromethyl amino alcohols and fluoroalkyl isoserinates. Hoffman reports the aysmmetric fluorination of a-aminoketones, while... 

An asymmetric synthesis of estrone begins with an asymmetric Michael addition of lithium enolate (178) to the scalemic sulfoxide (179). Direct treatment of the cmde Michael adduct with y /i7-chloroperbenzoic acid to oxidize the sulfoxide to a sulfone, followed by reductive removal of the bromine affords (180, X = a and PH R = H) in over 90% yield. Similarly to the conversion of (175) to (176), base-catalyzed epimerization of (180) produces an 85% isolated yield of (181, X = /5H R = H). C8 and C14 of (181) have the same relative and absolute stereochemistry as that of the naturally occurring steroids. Methylation of (181) provides (182). A (CH2)2CuLi-induced reductive cleavage of sulfone (182) followed by stereoselective alkylation of the resultant enolate with an allyl bromide yields (183). Ozonolysis of (183) produces (184) (wherein the aldehydric oxygen is by isopropyUdene) in 68% yield. Compound (184) is the optically active form of Ziegler s intermediate (176), and is converted to (+)-estrone in 6.3% overall yield and >95% enantiomeric excess (200). 

When n-BuLi is used instead of t-BuLi, the byproduct after desulfinylation (n-BuS(O)Ph) possesses an acidic proton, which is abstracted by the metalated epoxide. Hence, overall, a stereoselective protodesulfmylation is achieved. This can be used for the asymmetric synthesis of epoxides, such as that of (-)-disparlure from enantiopure sulfoxide 222 (Scheme 5.53) [78]. 

Pentitol synthesis An asymmetric synthesis of L-arabinitol involves condensation of the (E)-a,fJ-unsaturated ester (2) with the anion of methyl (R)-p-tolyl sulfoxide (1). The resulting p-keto sulfoxide (3) is reduced stereoselectively by ZnCl2/DIBAH (13, 115-116) to 4. Osmylation of 4 with (CH,)3NO and a catalytic amount of 0s04 (13, 224-225) yields essentially a single triol (5). Finally, a Pum-merer rearrangement of the sulfoxide followed by reduction of an intermediate... 

It should be noted that the related imine-oxaziridine couple E-F finds application in asymmetric sulfoxidation, which is discussed in Section 10.3. Similarly, chiral oxoammonium ions G enable catalytic stereoselective oxidation of alcohols and thus, e.g., kinetic resolution of racemates. Processes of this type are discussed in Section 10.4. Whereas perhydrates, e.g. of fluorinated ketones, have several applications in oxidation catalysis [5], e.g. for the preparation of epoxides from olefins, it seems that no application of chiral perhydrates in asymmetric synthesis has yet been found. Metal-free oxidation catalysis - achiral or chiral - has, nevertheless, become a very potent method in organic synthesis, and the field is developing rapidly [6]. 

Despite the low reactivity and poor stereoselectivity of compound 1 as a di-enophile, the main interest of the Maignan and Raphael s paper [5] derives from the fact that it was the first one involving the use of enantiomerically pure sulfoxides in Diels-Alder reaction, which would be used profusely later in asymmetric synthesis. For this reason it deserves some additional comments. From Scheme 2 can be deduced a moderate endo orientating character of the sulfinyl group [endo-adducts are the major ones (66%) in the mixture]. Although no explanation about the stereochemical behavior of compound 1 was offered in... 

These results indicate that the sulfinyl group seems to be much more efficient in the control of the stereoselectivity of 1,3-dipolar cycloadditions (endo or exo adducts are exclusively obtained in de> 80%) than in Diels-Alder processes (mixtures of all four possible adducts were formed). Additionally, complete control of the regioselectivity of the reaction was observed. Despite these clearly excellent results, the following paper concerning asymmetric cycloaddition of cyclic nitrones and optically pure vinyl sulfoxides was reported nine years later [154]. (Meanwhile, only one paper [155], related to the synthesis of /1-nicotyri-nes, described the use of reaction of nitrones with racemic vinyl sulfoxides, but these substrates were merely used as a masked equivalent of acetylene dipolaro-phile). In 1991, Koizumi et al. described the reaction of one of the best dipolarophiles, the sulfinyl maleimide 109, with 3,4,5,6-tetrahydropyridine 1-oxide 194 [154]. It proceeded in CH2C12 at -78 °C to afford a 60 20 10 6 mixture of four products in ca. 90 % yield (Scheme 92). 

Oxidation by chiral oxaziridines. For more than a decade, Davis s group49,71 76 has been working on the stoichiometric asymmetric oxidation of prochiral sulfides. In a series of elegant and important papers, they have demonstrated that their approach is one of the best methods in the synthesis of chiral sulfoxides. This research has yielded four generations of chiral oxaziridines 41- 44 exhibiting different stereoselectivities as a result of their dissimilar active-site structures (Fig. 5). 

During the past two decades, the asymmetric Diels-Alder reaction has become one of the most powerful tools in asymmetric synthesis as a result of its capacity to create up to four chiral centers in one step, often in a highly stereoselective manner. In the following sections, recent advances in this area using vinyl sulfoxide and vinyl sulfone dienophiles will be considered. It should be noted that, although beyond the scope of this review, many asymmetric Diels-Alder reactions of chiral sulfinyl-1,3-dienes have been reported.111... 

Major interest has been expressed in the synthesis of chiral sulfoxides since the early 1980s, when it was discovered that chiral sulfoxides are efficient chiral auxiliaries that are able to bring about important asymmetric transformations [22]. Sulfoxides are also constituents of important drugs (e.g., omeprazole (Losec , Priso-lec )) [23]. There is a plethora of routes of access to enantioenriched sulfoxides, and many involve metal-catalyzed asymmetric oxidations [24]. Examples of ruthenium metal-based syntheses of sulfoxides are scarce, presumably due to the tendency of sulfur atoms to bind irreversibly to a ruthenium center. Schenk et al. reported a dia-stereoselective oxidation of Lewis acidic Ru-coordinated thioethers with dimethyl-dioxirane (DMD) (Scheme 10.16) [25[. Coordination of the prochiral thioether to the metal is followed by diastereoselective oxygen transfer from DMD in high yield. The... 

They can also be used as vinylic carbanion species as shown by the asymmetric synthesis of the chro-man ring of vitamin The (E)/(Z) mixture of chiral sulfoxide (9) was readily isomerized into the ( )-isomer with LDA in THF (the exclusive formation of the ( )-isomer was due to the chelation of lithium with an oxygen of the acetal). Condensation to trimethylhydroquinonecarbaldehyde gave only one diastereoisomer and then the cyclization in presence of sodium methoxide was also fully stereoselective (the stereochemistry of the cyclization being controlled by that of the allylic hydroxy group which is eliminated during the cyclization Scheme 48). 

The first asymmetric total synthesis of the macrocyclic lactone metabolite (+)-pyrenolide D was accomplished in the laboratory of D.Y. Gin. The natural product has a densely functionalized polycyclic structure and its absolute configuration had to be established. The key step of the synthesis was a stereoselective oxidative ring-contraction of a 6-deoxy-D-gulal, which was prepared from anomeric allylic sulfoxide via the Mislow-Evans rearrangement. 

Efficient synthetic approaches to the optically active spiro-sulfuranes and their oxides have been reported by Martin and Drabowicz [65]. The preparation of optically active spirosulfuranes 45 and 46 was performed by asymmetric dehydration of the corresponding prochiral sulfoxide diols 47, as shown in Scheme 29. The optically active oxides 48 and 49 were prepared by oxidation of 45 and 46 with m-chloroperbenzoic acid (mCPBA). The synthesis of the optically active oxides was conducted by the stereoselective conversion of the chiral sulfuranes using Ru04, according to the procedure reported earlier [66]. 

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