Amides asymmetric hydroxylation

Diastereoselective hydroxylation of enolates of chiral amides. Davis and coworkers1 have examined the asymmetric hydroxylation of the tetrasubstituted enolates of a chiral amide (2) with these chiral camphoryloxaziridines. Oxidation of the lithium enolate of 2 with (+ )-l proceeds with only moderate diastereoselectivity (48.4% de), which is somewhat less than that observed on hydroxylation with the achiral 2-(phenylsulfonyl)-3-phenyloxaziridine (4). Oxidation of the enolate of 2... 

Asymmetric hydraxylation of lithium enolates of esters and amides.2 Hydroxylation of typical enolates of esters with ( + )- and (-)-l is effected in 75-90% yield and with 55-85% ee. The reaction with amide enolates with ( + )- and ( — )-l results in the opposite configuration to that obtained with ester enolates and with less enantioselectivity. Steric factors appear to predominate over metal chelation. 

The asymmetric hydroxylation of ester enolates with N-sulfonyloxaziridines has been less fully studied. Stereoselectivities are generally modest and less is known about the factors influencing the molecular recognition. For example, (/J)-methyl 2-hydroxy-3-phenylpropionate (10) is prepared in 85.5% ee by oxidizing the lithium enolate of methyl 3-phenylpropionate with (+)-( ) in the presence of HMPA (eq 13). Like esters, the hydroxylation of prochiral amide enolates with N-sulfonyloxaziridines affords the corresponding enantiomerically enriched a-hydroxy amides. Thus treatment of amide (11) with LDA followed by addition of (+)-( ) produces a-hydroxy amide (12) in 60% ee (eq 14). Improved stereoselectivities were achieved using double stereodifferentiation, e.g., the asymmetric oxidation of a chiral enolate. For example, oxidation of the lithium enolate of (13) with (—)-(1) (the matched pair) affords the a-hydroxy amide in 88-91% de (eq 15). (+)-(Camphorsulfonyl)oxaziridine (1) mediated hydroxylation of the enolate dianion of (/J)-(14) at —100 to —78 °C in the presence of 1.6 equiv of LiCl gave an 86 14 mixture of syn/anti-(15) (eq 16). The syn product is an intermediate for the C-13 side chain of taxol. 

Asymmetric hydroxylation of etiolates. Davis and Chen1 have reviewed this reaction using in particular (R,R)- and (S,S)-2-phenylsulfonyl)-3-phcnyloxaziridene (1) and (camphorylsulfonyl)oxaziridine (2). Of these reagents, 1 and ( + )- and (—)-2, derived from (lR)-lO-camphorsulfonic acid, provide highest enantioselectivity and in addition are easy to prepare. They are effective for hydroxylatation of ketones, esters, /2-keto esters, amides, lactones, and lactams. 

This asymmetric synthesis in a reaction with electrophiles is due to the chirality of the amide enolate created by the generation of intramolecular chelate of the enolate and the oxygen atom. An interesting fact is the effect of the group that participates in the chelation on the induced asymmetric centers. Hydroxyl and methoxyl induce formation of opposing asymmetric centers. Neither this fact nor the mechanism of the reaction and the intermediates involved has been discussed and explained. 

Oxaziridines. Davis has developed the use of chiral 2-sulfonyloxaziridines derived from camphorsulfonic acid as chiral auxiliaries in the asymmetric oxidation reactions. Although other oxaziridines may be preferable, the camphor-derived oxaziridines can be used for the oxidation of sulfides and disulfides to sulfoxides and thiosulfinates as well as for the epoxidation of alkenes. On the other hand, the camphoryloxaziridines are the preferred reagents for hydroxylation of lithium enolates of esters, amides, and ketones, as utilized in the synthesis of kjellmanianone (eq 17). ... 

Dihydrooxazoles continue to occupy an important place in organic synthesis and medicinal chemistry as they have found use as versatile synthetic intermediates, protecting groups/pro-drugs for carboxylic acids, and chiral auxiliaries in asymmetric synthesis. There are several protocols in the literature for the transformations of functional groups such as acids, esters, nitriles, hydroxyl amides, aldehydes, and alkenes to 2-oxazolines. Newer additions to these methods feature greater ease of synthesis and milder conditions. 

Novel organic molecules derived from L-proline and amines or amino alcohols, were found to catalyse the asymmetric direct aldol reaction with high efficiency. Notably those containing L-proline amide moiety and terminal hydroxyl group could catalyse direct asymmetric aldol reactions of aldehydes in neat acetone with excellent results[1]. Catalyst (1), prepared from L-proline and (IS, 2Y)-diphcnyl-2-aminoethanol, exhibits high enantioselectivities of up to 93% ee for aromatic aldehydes and up to >99% ee for aliphatic aldehydes. 

Reggelin and Brenig reported a different approach for the asymmetric synthesis on solid support (Scheme 1.6.38). An acylated Evans auxiliary was used as a soluble reagent for the transformation of polymer-supported aldehyde 81 into imide 82. The latter was converted into the Weinreb amide 83 which was - after protection of the hydroxyl group - submitted to DIBAH reduction to generate aldehyde 84. 

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