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Sulfoxides diastereoselectivity

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. [Pg.138]

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... [Pg.648]

The optimum conditions for obtaining a high diastereoselectivity are as follows Deprotonation of the sulfoxide must be carried out at 0 C with lithium diisopropyl amide (1 equiv). a lower temperature probably changes the organization of the lithium species and gives lower diastereoselectivity. The condensation reaction is very fast at —78 C, reaction time is usually around 10 minutes3. [Pg.771]

Lithium and zinc tert-butyl phenylmethyl sulfoxide (1) and A-phenyl imines 2, in which the substituent R is alkenyl or aryl, react at —78 °C over 2 hours with high anti diastereoselection (d.r. >98.5 1.5)6. Shorter reaction times result in poorer yields, due to incomplete reaction. In contrast, the reaction of the sulfoxide anion with benzaldehyde is complete after 5 seconds, but shows poor diastereoselection. When the substituent R1 or R2 of the imine 2 is aliphatic, the substrates exhibit poor chemical reactivity and diastereoselection. The high anti diastereoselection suggests that if a chelated cyclic transition state is involved (E configuration of the imine), then the boat transition state 4 is favored over its chair counterpart 5. [Pg.772]

The anions derived from racemic alkyl and benzyl tert-butyl sulfoxides undergo 1,4-addition to a,/J-unsaturated esters to give adducts with high product diastereoselection (>5 1)10,11. Alkyl 4-methylphenyl sulfoxides were found to be less diastereoselective. In the case of 2-methyl-2-(methylsulfinyl)propanc the highly hindered 2,6-di-rer7-butyl-4-methylphenyl ester was required to prevent a competing acylation reaction. [Pg.924]

Addition of racemic allylic sulfoxide anions to 2(5//)-furanone gives y-1,4-addition adducts1. The simple and induced diastereoselectivities are completely analogous to that of 2-cyclopen-tenone described earlier. [Pg.927]

The stereochemical outcome and the diastereoselectivity of the addition of the anion of diethyl propanedioate to a,/ -unsaturated sulfoxides is dependent on the reaction solvent, the metal counterion and the geometry of the a,/ -unsaturated sulfoxide1 - 3. [Pg.1041]

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. [Pg.1041]

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. [Pg.609]

Modena and colleagues47 have developed use of some chiral, non-racemic terpene alcohols as directing groups for highly diastereoselective m-chloroperbenzoic oxidation of sulfides into sulfoxides. Specifically the isobornyl vinylic sulfides 8 undergo hydroxyl-directed oxidation to give a 9 1 ratio of diastereomeric sulfoxides (equation 11). [Pg.828]

Enantiomerically pure /J-keto sulfoxides are prepared easily via condensation of a-lithiosulfinyl carbanions with esters. Reduction of the carbonyl group in such /J-keto sulfoxides leads to diastereomeric /J-hydroxysulfoxides. The major recent advance in this area has been the discovery that non-chelating hydride donors (e.g., diisobutylaluminium hydride, DIBAL) tend to form one /J-hydroxysulfoxide while chelating hydride donors [e.g., lithium aluminium hydride (LAH), or DIBAL in the presence of divalent zinc ions] tend to produce the diastereomeric /J-hydroxysulfoxide. The level of diastereoselectivity is often very high. For example, enantiomerically pure /J-ketosulfoxide 32 is reduced by LAH in diethyl ether to give mainly the (RR)-diastereomer whereas DIBAL produces exclusively the (.S R)-diastereomer (equation 30)53-69. A second example is shown in... [Pg.836]

Enantiomerically pure 3-tolyl-2-sulfinyl-2-cyclopentenone 37 undergoes smooth, mild and diastereoselective conjugate hydride addition with lithium tri(sec-butyl)borohydride to afford ultimately 3-tolylcyclopentanone 38 in 93% enantiomeric purity (equation 35)78. The absolute stereochemistry of product 38 is consistent with a chelated intermediate directing hydride addition from that diastereoface containing the sulfoxide lone pair. [Pg.839]

The enantiomerically pure, doubly activated a, /j-olefinic sulfoxides 46-5095 98 undergo highly diastereoselective Diels-Alder cycloadditions with cyclopentadiene, and pyridyl vinylic sulfoxide 5199 reacts diastereoselectively with furan. It is noteworthy that olefins singly-activated by only a sulfinyl group are not effective partners in Diels-Alder cycloadditions, as we have found after many attempts and as has been reported recently98. [Pg.845]

Racemic pyrone sulfoxide 52 undergoes a diastereoselective inverse-electron-demand 2 + 4-cycloaddition with 1,1-dimethoxyethylene to afford adduct 53 in > 95% yield (equation 49)100 this is the first example of an asymmetric Diels-Alder cycloaddition using a sulfinyldiene as an electron-deficient enophile101. [Pg.845]

S-aryl), concomitant sulfoxidation can be observed and the diastereoselectivity relative to the cis-diol depends on the nature of the sulfur substituents [239]. [Pg.259]

Recently, optically active (+)-(R)-methyl tolyl sulfoxide 102, R = H was alkylated with a very high diastereoselectivity The sulfoxide was treated with either lithium diisopropy-... [Pg.609]

Deprotonation of allylic aryl sulfoxides leads to allylic carbanions which react with aldehyde electrophiles at the carbon atom a and also y to sulfur . With benzaldehyde at — 10 °C y-alkylation predominates , whereas with aliphatic aldehydes at — 78 °C in the presence of HMPA a-alkylation predominates . When the a-alkylated products, which themselves are allylic sulfoxides, undergo 2,3-sigmatropic rearrangement, the rearranged compounds (i.e., allylic sulfenate esters) can be trapped with thiophiles to produce overall ( )-l,4-dihydroxyalkenes (equation 24). When a-substituted aldehydes are used as electrophiles, formation of syn-diols 27 occurs in 40-67% yields with diastereoselectivities ranging from 2-28 1 (equation 24) . ... [Pg.834]

Prior literature indicated that olefins substituted with chiral sulfoxides could indeed be reduced by hydride or hydrogen with modest stereoselectivity, as summarized in Scheme 5.10. Ogura et al. reported that borane reduction of the unsaturated sulfoxide 42 gave product 43 in 87 13 diastereomer ratio and D20 quench of the borane reduction mixture gave the product 43 deuterated at the a-position to the sulfoxide, consistent with the hydroboration mechanism [10a]. In another paper, Price et al. reported diastereoselective hydrogenation of gem-disubstituted olefin rac-44 to 45 with excellent diastereoselectivity using a rhodium catalyst [10b],... [Pg.152]

Other functional groups which have a heteroatom rather than a hydroxyl group capable of directing the hydrogenation include alkoxyl, alkoxycarbonyl, carboxylate, amide, carbamate, and sulfoxide. The alkoxy unit efficiently coordinates to cationic iridium or rhodium complexes, and high diastereoselectivity is induced in the reactions of cyclic substrates (Table 21.3, entries 11-13) [25, 28]. An acetal affords much lower selectivity than the corresponding unsaturated ketone (Table 21.3, entries 14 and 15) [25]. [Pg.650]

Figure 32.22 shows the diastereoselective hydrogenation of (R)-/ -keto sulfoxides with Meo-BIPHEP-Ru catalysts [72]. The R chiral center of the substrate matches with the S catalyst, giving the S,R alcohols in >99 1 selectivity, whereas reactions with the R catalyst affords a 6 94 to 10 90 mixture of the S,R and R,R diastereomeric alcohols. The diastereoselection is controlled mainly by the configuration of the catalyst. [Pg.1125]

Scheme 4.29 Diastereoselective sulfoxide formation in the axial series. Scheme 4.29 Diastereoselective sulfoxide formation in the axial series.

See other pages where Sulfoxides diastereoselectivity is mentioned: [Pg.75]    [Pg.75]    [Pg.136]    [Pg.137]    [Pg.924]    [Pg.926]    [Pg.74]    [Pg.834]    [Pg.836]    [Pg.840]    [Pg.183]    [Pg.186]    [Pg.187]    [Pg.146]    [Pg.169]    [Pg.74]    [Pg.836]    [Pg.840]    [Pg.187]    [Pg.164]    [Pg.250]    [Pg.355]    [Pg.582]    [Pg.681]    [Pg.1216]    [Pg.250]   
See also in sourсe #XX -- [ Pg.6 ]

See also in sourсe #XX -- [ Pg.900 ]

See also in sourсe #XX -- [ Pg.6 ]

See also in sourсe #XX -- [ Pg.900 ]




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