Asymmetric reactions chiral dipoles

To control the stereochemistry of 1,3-dipolar cycloaddition reactions, chiral auxiliaries are introduced into either the dipole-part or dipolarophile. A recent monograph covers this topic extensively 70 therefore, only typical examples are presented here. Alkenes employed in asymmetric 1,3-cycloaddition can be divided into three main groups (1) chiral allylic alcohols, (2) chiral amines, and (3) chiral vinyl sulfoxides or vinylphosphine oxides.63c... 

The carbo- and hetero-Diels-Alder reactions are excellent for the constmction of six-membered ring systems and are probably the most commonly applied cycloaddition. The 1,3-dipolar cycloaddition complements the Diels-Alder reaction in a number of ways. 1,3-Dipolar cycloadditions are more efficient for the introduction of heteroatoms and are the preferred method for the stereocontrolled constmction of five-membered heterocycles (1 ). The asymmetric reactions of 1,3-dipoles has been reviewed extensively by us in 1998 (5), and recently, Karlsson and Hogberg reviewed the progress in the area from 1997 and until now (6). Asymmetric metal-catalyzed 1,3-dipolar cycloadditions have also been separately reviewed by us (7-9). Other recent reviews on special topics in asymmetric 1,3-dipolar cycloadditions have appeared. These include reactions of nitrones (10), reactions of cyclic nitrones (11), the progress in 1996-1997 (12), 1,3-dipolar cycloadditions with chiral allyl alcohol derivatives (13) and others (14,15). 

The use of chiral azomethine imines in asymmetric 1,3-dipolar cycloadditions with alkenes is limited. In the first example of this reaction, chiral azomethine imines were applied for the stereoselective synthesis of C-nucleosides (100-102). Recent work by Hus son and co-workers (103) showed the application of the chiral template 66 for the formation of a new enantiopure azomethine imine (Scheme 12.23). This template is very similar to the azomethine ylide precursor 52 described in Scheme 12.19. In the presence of benzaldehyde at elevated temperature, the azomethine imine 67 is formed. 1,3-Dipole 67 was subjected to reactions with a series of electron-deficient alkenes and alkynes and the reactions proceeded in several cases with very high selectivities. Most interestingly, it was also demonstrated that the azomethine imine underwent reaction with the electronically neutral 1-octene as shown in Scheme 12.23. Although a long reaction time was required, compound 68 was obtained as the only detectable regio- and diastereomer in 50% yield. This pioneering work demonstrates that there are several opportunities for the development of new highly selective reactions of azomethine imines (103). 

Azomethine ylides are typical 1,3-dipoles, their participation in [3+2]cycloaddition is greatly influenced by Cu catalysts. Asymmetric reactions are realized by the addition of chiral ferrocene ligands such as 141 (called Fesulphos) and 142. ... 

The [3+2] cycloaddition strategy provides an effective method to access valuable intermediates for the construction of biologically important alkaloids, amino acids, amino carbohydrates and P-lactams [58-62]. The reaction involves the concerted pericyclic addition of a dipole and a dipolarophile and considerable efforts have been made to render these reactions asymmetric nsing Lewis acid catalysis and chiral anxiliaries [63]. 

Chiacchio et al. (43,44) investigated the synthesis of isoxazolidinylthymines by the use of various C-functionalized chiral nitrones in order to enforce enantioselec-tion in their cycloaddition reactions with vinyl acetate (Scheme 1.3). They found, as in the work of Merino et al. (40), that asymmetric induction is at best partial with dipoles whose chiral auxiliary does not maintain a fixed geometry and so cannot completely direct the addition to the nitrone. After poor results with menthol ester-and methyl lactate-based nitrones, they were able to prepare and separate isoxazo-lidine 8a and its diastereomer 8b in near quantitative yield using the A-glycosyl... 

The 1,3-dipolar cycloadditions of 1,3-dipoles with chiral alkenes has been extensively reviewed and thus only selected examples will be highlighted here. We have chosen to divide this section on the basis of the different types of alkenes rather than on the basis of the type of 1,3-dipole. For 1,3-dipolar cycloadditions, as well as for other reactions, it is important that the chiral center intended to control the stereoselectivity of the reaction is located as close as possible to the functional group of the molecule at which the reaction takes place. Hence, alkenes bearing the chiral center vicinal to the double bond are most frequently apphed in asymmetric 1,3-dipolar cycloadditions. Examples of the application of alkenes with the chiral center localized two or more bonds apart from the alkene will also be mentioned. Application of chiral auxiliaries for alkenes is very common and will be described separately in Section 12.3. 

An alternative approach in the asymmetric catalysis in 1,3-dipole cycloaddition has been developed by Suga and coworkers. The achiral 1,3-dipole 106 was generated by intramolecular reaction of an Rh(ii) carbene complex with an ester carbonyl oxygen in the Rh2(OAc)4-catalyzed diazo decomposition of <9-methoxycarbonyl-o -diazoacetophenone 105 (Scheme 12). The asymmetric induction in the subsequent cycloaddition to G=G and G=N bond was achieved by chiral Lewis acid Sc(iii)-Pybox-/-Pr or Yb(iii)-Pybox-Ph, which can activate the dipolarophile through complexation. With this approach, up to 95% ee for G=0 bond addition and 96% ee for G=G bond addition have been obtained, respectively. ... 

Nitrones were the first as well as the most widely used dipoles in asymmetric cycloadditions. The first report on the use of enantiomerically pure vinylsulf-oxides as dipolarophiles was due to Koizumi et al. [153], who described in 1982 the reaction of (-R)-vinyl p-tolyl sulfoxide 1 with acyclic nitrones 191. The reactions required 20 h in refluxing benzene to be completed, yielding a mixture of only two compounds, 192 and 193 (Scheme 91). They exhibited identical endo or exo stereochemistry (which was not unequivocally assigned), deduced from the fact that their reduction yielded enantiomeric thioethers. The major component, 192, exhibits (S) configuration at C-3, determined by chemical correlation. The authors claim this paper [153] to be the first example of 1,3-dipolar cycloaddition using chiral dipolarophiles. 

Cooper, D.M., Grigg, R., Hargreaves, S. ef a/. (1995) X = Y-ZH compounds as potential 1,3-dipoles. Part 44. Asymmetric 1,3-dipolar cycloaddition reaction of imines and chiral cyclic dipolarophiles. Tetrahedron, 51, 7791-7808. 

Dipolar cycloaddition reactions are not restricted to the use of alkene or alkyne dipolarophiles. Many hetero-dipolarophiles, particularly aldehydes and imines, undergo successful 1,3-dipolar cycloaddition with a range of 1,3-dipoles. The chemistry therefore provides access to a variety of five-membered heterocyclic compounds and compounds derived therefrom. Recent developments have focused on asymmetric dipolar cycloaddition reactions in the presence of a chiral catalyst, or the application of the chemistry to the preparation of biologically active compounds. 

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