Sulfoximines asymmetric synthesis

Racemic 5-methyl-5 -(sodiomethyl)-A-(4-methylphenylsulfonyl)sulfoximine reacts with ketones to give an initial methylene transfer which produces an intermediate epoxide that is ring expanded to the oxctanc56. Application to 4-rerf-butylcyclohexanonc affords a single oxetane in 69% yield. While only achiral alkylidcne transfer reagents were utilized, in principle this reaction is amenable to the asymmetric synthesis of oxetanes. 

Sulfoximines bearing a chiral sulfur atom have recently emerged as valuable ligands for metal-catalysed asymmetric synthesis.In particular, C2-symmetric bis(sulfoximines), such as those depicted in Scheme 1.51, were applied to the test reaction, achieving enantioselectivities of up to 93% ee. The most selective ligand (R = c-Pent, R = Ph) of the series was also applied to the nucleophilic substitution reaction of l,3-diphenyl-2-propenyl acetate with substituted malonates, such as acetamido-derived diethylmalonate, which provided the corresponding product in 89% yield and 98% ee. 

Gais and co-workers recently reported the preparation and use of chiral sulfoximine-substituted allyltitanium(iv) complexes of type 78 for the asymmetric synthesis of 3-substituted unsaturated proline derivatives 79 (Scheme 31).108... 

Scheme 1.3.2 Asymmetric synthesis of isocarbacyclin by the vinyl-allyl sulfoximine route.

Scheme 1.3.3 Asymmetric synthesis of cicaprost by the vinyl sulfoximine route.

Chiral alkenyl and cycloalkenyl oxiranes are valuable intermediates in organic synthesis [38]. Their asymmetric synthesis has been accomplished by several methods, including the epoxidation of allyl alcohols in combination with an oxidation and olefination [39a], the epoxidation of dienes [39b,c], the chloroallylation of aldehydes in combination with a 1,2-elimination [39f-h], and the reaction of S-ylides with aldehydes [39i]. Although these methods are efficient for the synthesis of alkenyl oxiranes, they are not well suited for cycloalkenyl oxiranes of the 56 type (Scheme 1.3.21). Therefore we had developed an interest in the asymmetric synthesis of the cycloalkenyl oxiranes 56 from the sulfonimidoyl-substituted homoallyl alcohols 7. It was speculated that the allylic sulfoximine group of 7 could be stereoselectively replaced by a Cl atom with formation of corresponding chlorohydrins 55 which upon base treatment should give the cycloalkenyl oxiranes 56. The feasibility of a Cl substitution of the sulfoximine group had been shown previously in the case of S-alkyl sulfoximines [40]. 

Scheme 1.3.21 Asymmetric synthesis of cycloalkenyl oxiranes via substitution of allyl sulfoximines.

Scheme 1.3.28 Asymmetric synthesis of bicyclic amino acids via Pauson-Khand cycloaddition of vinyl sulfoximines.

The oxidative imination of sulfides and sulfoxides via nitrene transfer processes leads to N-substituted sulfilimines and sulfoximines. This reaction is interesting as chiral sulfoximines are efficient chiral auxiliaries in asymmetric synthesis, a promising class of chiral ligands for asymmetric catalysis and key intermediates in the synthesis of pseudopeptides [169]. However, very few examples of such iron-catalyzed transformations have been described. 

This chapter reviews the applications of chiral sulfoximines to asymmetric and diastereoselective synthesis and as ligands in catalytic asymmetric synthesis.1 A number of studies have been performed on racemic substrates but only one enantiomer has been shown to assist the reader. In some schemes the S=N and/or the S=0 bond of the sulfoximine has been shown as a single bond. This is only for reasons of clarity. 

Sulfoximines are versatile reagents for diastereoselective and asymmetric synthesis. They continue to find many synthetic applications as both nucleophilic and electrophilic reagents. While the nucleophilic character of sulfoximine reagents has been well exploited,1 the use of the sulfoximine group as a nucleofuge is more recent and adds to the synthetic use of these compounds. The palladium(0)-catalyzed chemistry of allylic sulfoximines and the use of chiral sulfoximines as ligands in catalytic asymmetric synthesis are areas of recent development that have potentially useful applications. Further work is required to understand the factors that determine the diastereoselection and the stereochemical outcomes of these reactions. These studies will result in enhanced product diastereo- and enantioselectivities and make these reagents even more attractive to the wider synthetic chemistry community. 

CHIRAL SULFOXIMINES FOR DIASTEREOSELECTIVE AND ASYMMETRIC SYNTHESIS Stephen G. Pyne... 

Interestingly, when (1) reacted with allyltributyltin, no benzoth-iazine was formed at all. Instead, the allyl sulfoximine (2) was produced in 77% yield (eq 8). Although studies of the alkylation of the anion of 2 did not demonstrate high degrees of diastereoselection, subsequent work with allyUc sulfoximines demonstrated that such reagents could be quite useful in asymmetric synthesis. ... 

A model which rationalizes the sense of asymmetric induction has been proposed73. The alkenyl-sulfoximines 4 and 6 are useful intermediates in the synthesis of biologically active carbacyclins and isocarbacyclins 75- 77,78. 

We have developed asymmetric syntheses of isocarbacyclin [3] (Scheme 1.3.2) and cicaprost [4] (Scheme 1.3.3) featuring a Cu-mediated allylic alkylation of an allyl sulfoximine [5-7] and a Ni-catalyzed cross-coupling reaction of a vinyl sulf-oximine [8-10], respectively, transformations that were both developed in our laboratories. The facile synthesis of an allyl sulfoximine by the addition-elimination-isomerization route aroused interest in the synthesis of sulfonimidoyl-sub-stituted aiiyititanium complexes of types 1 and 2 (Fig. 1.3.2) and their application as chiral heteroatom-substituted allyl transfer reagents [11]. 

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