Chiral acetals nucleophilic additions

Chiral acetals can be used as auxiliaries in the diastereoselective reactions of Grignard reagents with acyclic as well as cyclic a-keto acetals. Nucleophilic addition to the monoprotected diketone (69 equation 18) occurs with excellent stereoselectivity to generate the corresponding tertiary alcohol (70) as the major product, usually with greater than 95 5 selectivity. Removal of the ketal yields a-hydroxy ketones of high optical purity. In most examples, enantiomeric excesses of 95% and higher are observed in the resultant keto alcohols. Table 17 represents the results of additions to cyclic and acyclic substrates. 

The high diastereoselectivity which is found in the nucleophilic addition of Grignard reagents to chiral 2-0x0 acetals can be explained by a chelation-controlled mechanism. Thus, coordination of the magnesium metal with the carbonyl oxygen and the acetal moiety leads to a rigid structure 3A in the transition state with preferred attack of the nucleophile occurring from the S/-side. 

The conversion of an a, -unsaturated aldehyde or ketone into an allylic acetal or ketal, followed by SN2 -type attack of a nucleophile, leads, after hydrolysis of an initially formed enol ether, to a fi-sub-stituted carbonyl compound. The overall sequence (Scheme 23) is equivalent to a direct conjugate addition, but has the advantage that it allows the temporary introduction of a chiral auxiliary group if a chiral (C2-symmetric) diol is used in the acetalization step, die subsequent nucleophilic addition leads to a mix-... 

The use of substituted pyridines in organic synthesis has broad application. The activation of the pyridine ring toward nucleophilic attack is well known in the literature. The products of such reactions are often dihydropyridines which can serve as intermediates in more complex synthetic strategies. Rudler and co-workers have reported on the nucleophilic addition of bis(trimethylsilyl)ketene acetals to pyridine (26). The 1,4-addition product 27 was then cyclized with iodine to afford bicycle 28 in 90% overall yield <02CC940>. Yamada has elegantly shown that facial selectivity can be achieved and chiral 1,4-dihydropyridines accessed in high yield and de (29—>30) <02JA8184>. 

Three new chirality centers are formed with high enantio- and complete diastereoselectivity in the course of the reaction of the enol triflate 37 to the bicyclo [3.3.0]octane derivative 38 (Scheme 11) [15]. In this transformation, the intermediate 39, formed by oxidative addition, leads to the cationic palladium-7r-allyl complex 40, which is finally converted to the isolated product 38 by regio- and diastereoselective nucleophilic addition of an acetate anion. The bicyclic product 38 is of interest as a building block for the synthesis of capnellene sesquiterpenes. 

Direct nucleophilic addition of potassium enolates derived from bis(trimethylsilyl)ketene acetals to aromatic chromium-complexed aromatic ethers affords meta substituted products (Scheme 124). A very high degree of asymmetric induction is obtained upon reaction of chiral arene chromium tricarbonyl complexes. For example, alkylation of complex (80)gave (81)afterdecomplexation(Scheme 125). ... 

Nucleophilic addition of ester enolates to enantiopure nitrones, followed by cyclization of the resulting hydro-xylamine, is a general approach to isoxazolidin-5-ones and can be applied to the stereoselective synthesis of these heterocycles <2005CRC775>. In some cases, the cyclization occurs spontaneously under the reaction conditions. For example, the addition of the sodium enolate of methyl acetate to chiral nitrone 551 gave directly the isoxazolidin-5-ones 552 in quantitative yield and high ty -diastereoselectivity (Equation 91) <1998CC493>. 

The chiral auxiliary mediated aza-Claisen rearrangement of /V-allylketcnc. V.O-acetals also allows the diastereoselective construction of quaternary carbon centers642. Butyllithium proved to be an unsuitable base for the neutralization step in this case because the increased steric hindrance at C-l causes C-2 nucleophilic addition to become competitive with C-l deprotonation. However, this problem can be overcome by the use of lithium tov-butoxide or lithium isopropoxide. This is shown for the achiral. V-allylketene A. O-aceta] precursor 8. 

Significant advances have been made in asymmetric nucleophilic additions to -ir-allyl palladium complexes using chiral ligands. Substitution of allylic acetates in the presence of the chiral phosphine hgand 224 (or other chiral phosphine ligands) can occur with very high levels of enantioselection (1.224). The reaction works best with diaryl-substituted allylic acetates. 

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