Chemoselectivity other donors

The concept of armed/disarmed glycosyl donors was subsequently extended by other groups to thioglycosides21 and selenoglycosides.64 A similar strategy has been used by Friesen and Danishefsky to achieve chemoselectivity in electrophilic addition to glycal double bonds.65... 

Hydrolase-catalyzed enantioselective N-acylation is an important tool for the preparation of enantiopure a- and P-aminoacids. It has been observed that the reactions of many amino acid esters with ester acyl donors catalyzed by CALB is sometimes complicated by interesterification reactions. CALA has, however, emerged as a very chemoselective catalyst in favor of N-acylation of P-aminoesters. Some reviews on CALA and other hydrolases as catalysts for N-acylations of aminoesters are available [109, 126, 127]. 

To make as much carboxylic acid derivative as possible available to the nucleophile at all stages of the reaction, the nucleophile is added dropwise to the carboxylic acid derivative and not the other way around. In Figure 6.41, the approach to chemoselective acylations of hydride donors and organometallic compounds, which we have just described, is labeled as strategy 2 and compared to two other strategies, which we will discuss in a moment. 

In the addition of hydride donors to aldehydes (other than formaldehyde) the tetrahedral intermediate is a primary alkoxide. In the addition to ketones it is a secondary alkoxide. When a primary alkoxide is formed, the steric hindrance is smaller. Also, when the C=0 double bond of an aldehyde is broken due to the formation of the CH(0 M ) group of an alkoxide, less stabilization of the C=0 double bond by the flanking alkyl group is lost than when the analogous transformation occurs in a ketone (cf. Table 9.1). For these two reasons aldehydes react faster with hydride donors than ketones. With a moderately reactive hydride donor such as NaBH4 at low temperature one can even chemoselectively reduce an aldehyde in the presence of a ketone (Figure 10.6, left). 

Replacing the oxygen atom of the Fischer carbene with other heteroatoms provides a valuable variation. Arylaminocarbenes show a marked chemoselectivity for producing the indane nucleus, which is attributed to the stronger donor character of the amino group relative... 

Trost coined the term chemoselective to describe the process where one of two similar functional groups is made to react, while the other is not affected or affected to a lesser extent [1]. This discrimination usually results from nuanced changes to a reagent s behavior, e.g., by addition of a salt. A typical example is the modification of sodium borohydride reduction by addition of cerium chloride in the Luche process, whereby the double bond of an ot-enone is not saturated during the reaction [85]. Similarly, a new approach to chemoselective reaction of n-pentenyl donors was soon to emerge. 

The result is reminiscent of the original armed/disarmed experiment (Scheme 3) in that each reactant (75 or 76) can serve, separately, as a donor, but when they are forced to compete, one becomes the acceptor and the other the donor, thereby satisfying the condition for chemoselectivity. 

That acyl-protecting groups deactivate glycosyl donors in comparison to other counterparts had been known. Why the disparity had not been earlier exploited for synthetic advantage is open to speculation. However, experiments in our laboratory suggest that if the disarmed partner is too reactive, chemoselectivity will be poor - a condition that would apply to glycosyl bromides, the major donors then in use. 

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