Sulfoxide diastereomer

Scheme 18.27 Only one sulfoxide diastereomer undergoes Mislow-Evaas rearrangement in modular approach to tetracycline analogue synthesis.—...

Zakarian s group encountered contrasting reactivity, however, when attenpting to carry out a similar Claisen/Mislow-Evans cascade toward the preparation of (-)-joubertinamine and (-)-mesembrine, psychoactive alkaloids from plants of the sceletium family f Scheme 1 R..SOT hi this case, only starting material was recovered when either sulfoxide diastereomer of vinyl sulfoxide 194 was heated under conditions that had given smooth rearrangement of 191 in the pinnatoxin approach (compare Schemes 49 and 50), and at higher temperatures, vinyl sulfoxide... 

The methyl ester of 208 was reduced and the resulting primary alcohol activated and homologated to yield 209. Oxidation of the sulfide gave a mixture of sulfoxide diastereomers. 

Radical-mediated reductive dechlorination (BusSnH/AIBN/benzene/A) of purified 23a(5 S, Ss) and 24a(5 R, Sg) gave the sulfoxide diastereomers 21b(S j) and 22b(Ss), respectively, with retention of stereochemistry at sulfur ( H NMR). No changes were observed upon control treatment of 21b or 22b (BusSnH/AIBN/benzene/A). Thus, the stereochemistry at sulfur in the two major a-chloro sulfoxide diastereomers (as well as in... 

Scheme 1-64. Reaction of methyllithium with steroidal sulfoxide diastereomers. ...

Besides simple alkyl-substituted sulfoxides, (a-chloroalkyl)sulfoxides have been used as reagents for diastereoselective addition reactions. Thus, a synthesis of enantiomerically pure 2-hydroxy carboxylates is based on the addition of (-)-l-[(l-chlorobutyl)sulfinyl]-4-methyl-benzene (10) to aldehydes433. The sulfoxide, optically pure with respect to the sulfoxide chirality but a mixture of diastereomers with respect to the a-sulfinyl carbon, can be readily deprotonated at — 55 °C. Subsequent addition to aldehydes afforded a mixture of the diastereomers 11A and 11B. Although the diastereoselectivity of the addition reaction is very low, the diastereomers are easily separated by flash chromatography. Thermal elimination of the sulfinyl group in refluxing xylene cleanly afforded the vinyl chlorides 12 A/12B in high chemical yield as a mixture of E- and Z-isomers. After ozonolysis in ethanol, followed by reductive workup, enantiomerically pure ethyl a-hydroxycarboxylates were obtained. 

The reaction of the anion of an aryl allyl sulfoxide with benzaldehyde can take place via an a or y attack. The a attack leads to a product with three stercogcnic centers (four possible diastereomers) whereas the y attack results in a product which has only two stereogenie centers and geometric isomerism is possible. 

More recently the stereoselectivity of the addition of sulfinyl anions to carbonyl groups was improved by introducing a sulfide group in the a-position30,31. The sulfoxide ( + )-(S)-(4-methylphcnylsulfinyl)(4-methylphenylthio)metliane was added to benzaldehyde to give the adduct 1 as a mixture of three diastereomers [(S5,15,27 )/(SS,17 ,2/J)/(S5,15,25) 55 30 15] which could be transformed into the corresponding a-methoxyaldehydc 4 in 67% yield with 70 % ee. The same reaction, when applied to phenylacetaldehyde, led to a product in 43 % yield with lower ee (46%). 

The ( + )-(/ )-methyl 4-tolyl sulfoxide anion from 1 reacts with nitrones 2 to afford optically active hydroxylamines with very high fi stereoselectivity5. The diastereomeric ratio of the products 3 a, b varies from d.r. 75 25-100 0, the highest being for R = t-Bu. The configuration of the diastereomers 3 a, b has not been determined. 

With sulfoxides Ar(SO)CH2R four diastereomers are generated in principle. Only the aspect of simple diastcreoselectivity has been investigated so far. 

The addition of the anion of the racemic 2-methyl-2-propenyl sulfoxides, rac-2-methyl-3-(phenyl-sulfinylpl-propene and /w-3-(rerr-butylsulfinyl)-2-methyl-l-propene to 2-cyclopentenone gives mixtures of (E)- and (Z )-y-l, 4-addition products which are a mixture of diastereomers at sulfur2. The (T )-products usually predominate, with the relative proportions of the (Z)-product increasing as the reaction temperature is increased. No asymmetric induction originating from the stereocenter at sulfur was observed when the sulfoxide substituent was phenyl however, there was a marginal improvement in the case of the (Zi)-product when the sulfoxide substituent was ferf-butyl. 

The addition of the anion of the 1,3-dimethyl-2-butenyl sulfoxides to 2-cyclopentenone was examined2. The anion of rar-2-methyl-4-(phenylsulfinyl)-2-pentene gave a 50 50 mixture of ( )- and (Z)-y-1,4-adducts which differed in the relative configuration of the new stereocenter regarding the stereocenter at sulfur. That is, for either the (Z)- or the ( )-product there is complete asymmetric induction from the stereocenter at sulfur, but in the opposite direction. When the rm-butyl analog, ruc-4-(/wt-butylsulfinyl)-2-methyl-2-pcntcne, was reacted, it gave exclusively the ( )-adduct, likewise as a single diastereomer. 

The addition of enolate anions to (E)- and (Z)-3,3,3-trifluoro-l-[(4-methylphenyl)sulfinyl]-1 -propene has been investigated (E)- and (Z)-a,/(-unsaturated sulfoxides undergo addition in the opposite stereochemical sense3,4. In general, yields and product diastereoselection are high. When the -position of the double bond of the enolate is substituted then all four diastereomer-ic products result. 

Sulfoxides were first prepared in optically active form in 1926 by the classical technique of diastereomeric salt formation followed by separation of the diastereomers by recrystallization16 17. Sulfoxides 1 and 2 were treated with d-camphorsulfonic acid and brucine, respectively, to form the diastereomeric salts. These salts were separated by crystallization after which the sulfoxides were regenerated from the diastereomers by treatment with acid or base, as appropriate. Since then numerous sulfoxides, especially those bearing carboxyl groups, have been resolved using this general technique. 

Ueno and coworkers49 have developed a procedure for the synthesis of chiral sulfinic acids. Treatment of (R)-( + )-23 with disulfide 24 and tributylphosphine in THF gave (S)-( — )-25. Compound 25 was oxidized with potassium permanganate to the sulfone, which was then reduced to the sulfinic acid, (S)-( — )-26, by treatment with sodium borohydride. Conversion of 26 or an analog to an ester would lead to diastereomers. If these epimers could be separated, then they would offer a path to homochiral sulfoxides with stereogenic carbon and sulfur atoms. 

Aryl- and alkyl-magnesium halides were the first reagents used to form sulfoxides from sulfinate ester 19 and related (— )-menthyl arenesulfinates (equations 564,665,758 and 866). Whereas optically pure esters produced the homochiral sulfoxides shown in equations (5), (6) and (7), the ester shown in equation (8) was an oily mixture of four diastereomers which led to formation of a meso sulfoxide and a d, l pair enriched in one enantiomer. A homochiral sulfoxide was obtained by fractional crystallization. 

An a-phosphoryl sulfoxide (4) has also been prepared by the reaction of the appropriate carbanion with sulfinate ester 19 (see also Section II.A.l)18. Ugi and coworkers prepared (S, R, S)-65 by reaction of (R, R)-64 with ester 19. The (S, S, R) diastereomer was prepared from (S, S)-6496. 

Sulfoxides (R1—SO—R2), which are tricoordinate sulfur compounds, are chiral when R1 and R2 are different, and a-sulfmyl carbanions derived from optically active sulfoxides are known to retain the chirality. Therefore, these chiral carbanions usually give products which are rich in one diastereomer upon treatment with some prochiral reagents. Thus, optically active sulfoxides have been used as versatile reagents for asymmetric syntheses of many naturally occurring products116, since optically active a-sulfinyl carbanions can cause asymmetric induction in the C—C bond formation due to their close vicinity. In the following four subsections various reactions of a-sulfinyl carbanions are described (A) alkylation and acylation, (B) addition to unsaturated bonds such as C=0, C=N or C= N, (C) nucleophilic addition to a, /5-unsaturated sulfoxides, and (D) reactions of allylic sulfoxides. 

Recently, optically active (+)-(R)-methy 1 tolyl sulfoxide 102, R = H was alkylated with a very high diastereoselectivity136. The sulfoxide was treated with either lithium diisopropy-lamide (LDA) or lithium tetramethylpiperidide (LTMP) to form the lithio-derivative, which upon subsequent reaction with lithium a-bromomethyl acrylate gave a mixture of two diastereomers of a-methylene-y-sulfinylcarboxylic acid 103. The use of the sterically highly hindered base, LTMP, gave the product with a higher diastereoselectivity. For example, the Sc4 Rc4 ratio was 95 5 when R was the methyl group. 

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