Esters chemoselective

The hydrolysis of phosphonic acid esters in Brij-35 micelles by cerium(IV) was investigated by Moss and Ragunathan (1999). The phosphonic esters differ from the phosphodiesters by the presence of only one ester bond and by a direct bond between phosphorus and the carbon atom of an alkyl or aryl group. Cerium(IV) ions also accelerate the hydrolysis of these diesters (Moss and Morales-Rojas, 2001 Moss et al., 2004). The phosphonoformate diesters show structural similarities with the phosphodiesters. Whereas zirconium(IV) and hafnium(IV) hydrolyze mainly the P-OR bond, cerium(IV) and thorium(IV) hydrolyze principally the C-OR bond in the phosphonoformate diesters. This chemoselective ester hydrolysis was not observed for the phosphodiester compounds. 

The a, /3-epoxy ketone 119 and esters are hydrogenolyzed with triethylam-monium formate or H2 chemoselectively to aldols[116]. 

Huonnations with DAST proceed with high chemoselectivity In general, under very mild reaction conditions usually required for the replacement of hydroxyl groups, other functional groups, including phenolic hydroxyl groups [112], remain intact This provides a method for selective conversion of hydroxy esters [95 97] (Table 6), hydroxy ketones [120, 121], hydroxy lactones [722, 123], hydroxy lactams [124] and hydroxy nitriles [725] into fluoro esters, fluoro ketones, fluoro lactones, fluoro lactams, and fluoro nitnles, respectively (equations 60-63)... 

A synthetically useful virtue of enol triflates is that they are amenable to palladium-catalyzed carbon-carbon bond-forming reactions under mild conditions. When a solution of enol triflate 21 and tetrakis(triphenylphosphine)palladium(o) in benzene is treated with a mixture of terminal alkyne 17, n-propylamine, and cuprous iodide,17 intermediate 22 is formed in 76-84% yield. Although a partial hydrogenation of the alkyne in 22 could conceivably secure the formation of the cis C1-C2 olefin, a chemoselective hydrobora-tion/protonation sequence was found to be a much more reliable and suitable alternative. Thus, sequential hydroboration of the alkyne 22 with dicyclohexylborane, protonolysis, oxidative workup, and hydrolysis of the oxabicyclo[2.2.2]octyl ester protecting group gives dienic carboxylic acid 15 in a yield of 86% from 22. 

It has been reported that an allylic C-Si bond can be cleaved by tetrabutylammonium fluoride to give an anionic allylic species, which chemoselectively adds to carbonyl compounds (nitriles, esters, and epoxides failed) to form homoallylsilyloxy compounds13. 

The compound NaBH4 in the presence of Me2N=CHCl" Cl" reduces carboxylic acids to primary alcohols chemoselectively in the presence of halide, ester, and nitrile groups Fujisawa, T. Mori, T. Sato, T. Chem. Lett., 1983, 835. 

This looks at first sight like a formidable problem of chemoselectivity, but changing the oxidation level to an aldehyde (25) gives a simple 1,3-diX disconnection to available aldehyde (26). The ester would have done as well. 

Removing the substituted hydrazine (58) leaves acetoacetic ester (57). Phenylhydrazine is available, so it is easier to make (59) and methylate afterwards. This removes the chemoselectivity problem as the more nucleophilic NH group attacks the more electrophilic ketone. 

Hydrolysis of both ester groups and chemoselective re-esterification of the more reactive alkyl acid... 

Searching for a method of synthesis of enantiopure lamivudine 1, the compound having a monothioacetal stereogenic centre, Rayner et al. investigated a lipase-catalysed hydrolysis of various racemic a-acetoxysulfides 2. They found out that the reaction was both chemoselective (only the acetate group was hydrolysed with no detectable hydrolysis of the other ester moieties) and stereoselective. As a result of the kinetic resolution, enantiomerically enriched unreacted starting compounds were obtained. However, the hydrolysis products 3 were lost due to decomposition." In this way, the product yields could not exceed 50% (Equation 1). The product 2 (R = CH2CH(OEt)2) was finally transformed into lamivudine 1 and its 4-epimer. ... 

Hydrozirconation of various alkenylboranes [118-121] and alkenylzinc halides [34] with 1 provides the corresponding 1,1-bimetalloalkanes, which can be selectively converted to functionalized organic compounds [122-125]. Interestingly, alkenylzinc halides (RCH=CHZnX) show remarkable chemoselectivity, and functional groups such as chloride, cyanide, or ester functionality are tolerated [126]. 

Branched-regioselective hydroformylation of unsaturated esters has been achieved [41]. The use of the phosphaadamantane ligand 1, which is readily available from acetylacetone and phenylphosphine (Eq. 1), proved particularly useful in terms of reaction rate, regio-, and chemoselectivity [42-44]. 

Hydroformylation of a range of 1,1-di- and 1,1,2-trisubstituted unsatur-ated esters yields quaternary aldehydes (Table 1, entries 1-8). Hence, the regiochemistry-directing influence of the electron-withdrawing ester function overcompensates Keuleman s rifle. Furthermore, hydroformylation of 1,2-disubstituted unsaturated esters occurred with high a-selectivity and chemoselectivity (Table 1, entries 9 and 10). As a side reaction hydrogenation of the alkene has been observed [41]. 

The Pd°-catalyzed transformation of enediynes represents a highly efficient and effective approach for the synthesis of polycyclic compounds, with different ring sizes being obtained by a variation of the tether [129]. In this respect, reaction of 6/1-270 led to the tricyclic product 6/1-271 as a single diastereomer. The initial step is a chemoselective hydropalladation of the propargylic ester moiety in 6/1-270 to give an alkenyl-Pd-species, according to the mechanism depicted in Scheme 6.71. A hexatriene is formed as a byproduct. 

Elaboration of triol 88b to bryostatin 7 requires chemoselective hydrolysis of the Cl methyl ester in the presence of the C7 and C20 acetates, macrolide formation, installation of the C13 and C21 methyl enoates, and, finally, global deprotection. The sequencing of these transformations is critical, as attempts to introduce the C21 methyl enoate to form the fully functionalized C-ring pyran in advance of macrolide formation resulted in lactonization onto the C23 hydroxyl. In the event, trimethyltin hydroxide promoted hydrolysis [73] of the Cl carboxylate of triol 88b, and subsequent trie thy lsilylation of the C3 and C26 hydroxyls each occurs in a selective fashion, thus providing the seco-acid 89. Yamaguchi macrolacto-nization [39] proceeds uneventfully to provide the macrolide 67 in 66 % yield (Scheme 5.14). 

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