Substrate-directed diastereoselective reagents

Conversely, the addition of enantiomerically pure chiral dialkylboranes to enantiomerically pure chiral alkenes can also take place in such a way that substrate control and reagent control of diastereoselectivity act in the same direction. Then we have a matched pair. It reacts faster than the corresponding mismatched pair and with especially high diastereoselectivity. This approach to stereoselective synthesis is also referred to as double stereodifferentiation. 

For weak acids, the proton is directly transferred from the acid to the substrate in a reagent-controlled manner and, in order to increase the selectivity, extremely shielded 2 -substituted m-terphenyls have been developed as concave protonating reagents inspired by the geometry of enzymes. Thus, the diastereoselective protonation by a series of substituted phenols of endocyclic keto enolates, obtained by the stereocontrolled 1,4-addition of lithiocuprates onto substituted cyclohexenones, was reported by Krause and coworkers354 355 and applied to the synthesis of racemic methyl dihydroepijasmonate356. 

If, as in the reaction example in Figure 3.32, during the addition to enantiomerically pure chiral alkenes, substrate and reagent control of diastereoselectivity act in opposite directions, we have a so-called mismatched pair. For obvious reasons it reacts with relatively little diastereoselectivity and also relatively slowly. Side reactions and, as a consequence, reduced yields are not unusual in this type of reaction. However, there are cases in which mismatched paris still give rise to highly diastereoselective reactions, just not as high as the matched pair. 

The nitrido complex was applied to the direct asymmetric animation with a silyl enol ether as a substrate. Although several examples for achiral aminations of silyl enol ethers have been reported [32], an asymmetric version of reagent-controlled reaction has not appeared except for the one recent example [33] and the diastereoselective reactions with silyl enol ethers having a chiral auxiliary [34], The amination, which is presumed to take place via an aziridine intermediate [5g, lid,32], proceeded smoothly to give the A-tosylated a-aminoketone in 76% yield with 48% ee. When the same silyl enol ether was treated with complex 15 under Carreira s condition, the TV-trifluoroacetylated a-aminoketone was obtained in 58 % yield with 79 % ee (Scheme 24). 

Active Substrate. If a new chiral center is created in a molecule that is already optically active, the two diastereomers are not (except fortuitously) formed in equal amounts. The reason is that the direction of attack by the reagent is determined by the groups already there. For certain additions to the carbon-oxygen double bond of ketones containing an asymmetric a carbon. Cram s rule predicts which of two diastereomers will predominate (diastereoselectivity). The reaction of 46, which has a stereogenic center at the ot-carbon, and HCN can generate two possible diastereomers. 

Acyl Anion Conjugate Additions. The lithio reagent readily undergoes 1,4-addition to unsaturated substrates (eq 6), in direct contrast to the corresponding 2-lithio-2-trimethylsilyl-l,3-dithiane, which is a poor Michael donor. The initial Michael adducts can also be alkylated to provide highly functionalized products. Very good levels of diastereoselectivity have been observed in the 1,4-addition and enolate alkylations of cyclic enoates (eq 7)2 and acyclic enones (eq 8). ... 

These reagents are used either in diastereoselective electrophilic fluorinations for which the stereoselectivity is directed intramolecularly by an enantiopure substrate, often of natural origin, or having a temporary attached chiral auxiliary or in enantioselective electrophilic fluorinations of achiral substrates with the aid of a chiral reagent or catalyst. 

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