Chiral amino alcohols, enantioselective

RCH =CHBCy2, R2Zn, chiral amino alcohol (enantioselective)... 

R2Zn, several chiral amino alcohols (enantioselective) 1L 25 2823 (1984) (FhCHO only) 28 6163 (1987) (ArCHO only) 30 6427 (1989)... 

The most successful of the Lewis acid catalysts are oxazaborolidines prepared from chiral amino alcohols and boranes. These compounds lead to enantioselective reduction of acetophenone by an external reductant, usually diborane. The chiral environment established in the complex leads to facial selectivity. The most widely known example of these reagents is derived from the amino acid proline. Several other examples of this type of reagent have been developed, and these will be discussed more completely in Section 5.2 of part B. 

Since the addition of dialkylzinc reagents to aldehydes can be performed enantioselectively in the presence of a chiral amino alcohol catalyst, such as (-)-(1S,2/ )-Ar,A -dibutylnorephedrine (see Section 1.3.1.7.1.), this reaction is suitable for the kinetic resolution of racemic aldehydes127 and/or the enantioselective synthesis of optically active alcohols with two stereogenic centers starting from racemic aldehydes128 129. Thus, addition of diethylzinc to racemic 2-phenylpropanal in the presence of (-)-(lS,2/ )-Ar,W-dibutylnorephedrine gave a 75 25 mixture of the diastereomeric alcohols syn-4 and anti-4 with 65% ee and 93% ee, respectively, and 60% total yield. In the case of the syn-diastereomer, the (2.S, 3S)-enantiomer predominated, whereas with the twtf-diastereomer, the (2f ,3S)-enantiomer was formed preferentially. 

Although it is known that in some cases the lithium salts of chiral amino alcohols are even better catalysts than the chiral ligands themselves, the use of metals other than lithium has rarely been investigated. The oxazaborolidines A and B and the aluminum analog C have been used as catalysts for the enantioselective addition of diethylzinc to benzaldehyde35 (Table 32). 

Catalytic amounts of chiral amino alcohols both catalyze the reactions of alkylzinc reagents with aldehydes and induce a high degree of enantioselec-tivity. Two examples are given below. Formulate a mechanism for this catalysis. Suggest transition structures consistent with the observed enantioselectivity. 

The hydrogenation of a series of E/Z-isomeric mixtures of a-arylenamides with a MOM-protected /1-hydroxyl group catalyzed by a Rh-complex of 1,4-dipho-sphane T-Phos with a rigid 1,4-dioxane backbone led to chiral / -amino alcohol derivatives in excellent enantioselectivities (Scheme 26.4) [55]. DIOP -Rh is also effective for this transformation [51b]. 

Since the discovery of the CBS catalyst system, many chiral //-amino alcohols have been prepared for the synthesis of new oxazoborolidine catalysts. Compounds 95 and 96 have been prepared93 from L-cysteine. Aziridine carbi-nols 97a and 97b have been prepared94 from L-serine and L-threonine, respectively. When applied in the catalytic borane reduction of prochiral ketones, good to excellent enantioselectivity can be attained (Schemes 6-42 and 6-43). 

The earliest enantioselective Reformatsky reaction was reported in 1973.52 Compound (-)-spartein was used as the chiral ligand, but the reaction gave rather low yield. Almost 20 years later, in 1991, Soai and Kawase53 reported an enantioselective Reformatsky reaction in which chiral amino alcohol 58 or 59 was used as the ligand. Aliphatic and aromatic //-hydroxy esters were obtained with moderate to good yields. 

Fluorine-containing compounds can also be synthesized via enantioselective Reformatsky reaction using bromo-difluoroacetate as the nucleophile and chiral amino alcohol as the chiral-inducing agent.86 As shown in Scheme 8-41, 1 equivalent of benzaldehyde is treated with 3 equivalents of 111 in the presence of 2 equivalents of 113, providing a,a-difluoro-/ -hydroxy ester 112 at 61% yield with 84% ee. Poor results are observed for aliphatic aldehyde substrates. For example, product 116 is obtained in only 46% ee. 

Enantioselective addition of CjH zZn to aldehydes.1 Addition of diethylzinc to either aromatic or aliphatic aldehydes catalyzed by 1 (6 mole %) results in (S)-secondary alcohols in generally 90-95% ee. Although several chiral amino alcohols are known to effect enantioselective addition of R2Zn to aromatic aldehydes, this one is the first catalyst to be effective for aliphatic aldehydes. The dibutylamino group of 1 is essential for the high enantioselectivity the dimethylamino analog of 1, (lS,2R)-N-methylephedrine, effects this addition in only about 60% ee. 

Similar results were obtained by Suzuki et al. (55) in their investigation of enantioselective addition of Et2Zn to various N-diphenylphosphinylimines with PAMAM dendrimers functionalized with 4 and 8 chiral amino alcohol groups. They observed 92% ee for the monomeric ligand, 43% ee for GO, and 30—39% ee for G1 when using N-diphenylphosphinylbenzaldimine as the substrate. Again, a high local concentration of chiral active sites leads to a decrease in enantioselectivity. 

Ricci and co-workers introduced a new class of amino- alcohol- based thiourea derivatives, which were easily accessible in a one-step coupling reaction in nearly quanitative yield from the commercially available chiral amino alcohols and 3,5-bis(trifluoromethyl)phenyl isothiocyanate or isocyanate, respectively (Figure 6.45) [307]. The screening of (thio)urea derivatives 137-140 in the enantioselective Friedel-Crafts reaction of indole with trans-P-nitrostyrene at 20 °C in toluene demonstrated (lR,2S)-cis-l-amino-2-indanol-derived thiourea 139 to be the most active catalyst regarding conversion (95% conv./60h) as well as stereoinduction (35% ee), while the canditates 137, 138, and the urea derivative 140 displayed a lower accelerating effect and poorer asymmetric induction (Figure 6.45). The uncatalyzed reference reaction performed under otherwise identical conditions showed 17% conversion in 65 h reaction time. 

The first report in this regard described a method for direct formation of the desired optically active (S)-alcohol 32a, via enantioselective reduction with a chiral amine complex of lithium aluminum hydride (Scheme 14.9). Therefore, the necessary chiral hydride complex 38 was preformed in toluene at low temperature from chiral amino alcohol 37. The resulting hydride solution was then immediately combined with ketone 31 to afford the desired (S)-alcohol 32a in excellent yield and enantiomeric excess. In addition to providing a more efficient route to the desired drug molecule, this work also led to the establishment of the absolute configuration of duloxetine (3) as S). 

It has recently been shown that when the tetrahedral intermediate of the reaction is cyclic, it is a better donor of nucleophilic CF3. These cyclic intermediates can be generated intramolecularly from trifluoroacetamides or trifluorosulfmamides derived from (9-silylated ephedrine. These reagents are able to trifluoromethylate aldehydes and ketones, even in the case of enolizable substrates, as a strong base is not required (Figure 2.34). However, while the source of CF3 is chiral, there is no chirality transfer to the addition product, and the replacement of ephedrine by other chiral amino alcohols did not show any improvement. " Similar to asymmetric trifluoromethylation with the Ruppert reagent, only the use of a fluoride salt of cinchonine can increase the enantioselectivity. " " ... 

The above azomethine ylide cycloadditions have been extended to an enantioselective version involving amino alcohols both as chiral ligands and amine bases. Thus, reactions of the N-metalated azomethine yhdes derived from achiral methyl 2-(arylmethyleneamino)acetates, cobalt(II) chloride [or manganese(II) bromide], and chiral amino alcohols, 1 and 2 equiv each, with methyl acrylate as solvent have been performed to provide the enantiomer-enriched pyrrolidine-2,4-dicarboxylates with the enantioselectivities of up to 96% enantiomeric excess (ee) (128,129). However, a large excess of the metal ions and the chiral source (ligand and base) have to be employed. 

Chirality plays a central role in the chemical, biological, pharmaceutical and material sciences. Owing to the recent advances in asymmetric catalysis, catalytic enantioselective synthesis has become one of the most efficient methods for the preparation of enantiomer-ically enriched compounds. An increased amount of enantiomerically enriched product can be obtained from an asymmetric reaction using a small amount of an asymmetric catalyst. Studies on the enantioselective addition of dialkylzincs to aldehydes have attracted increasing interest. After the chiral amino alcohols were developed, highly enantioselective and reproducible —C bond forming reactions have become possible. 

The amino alcohol-catalyzed enantioselective addition of dialkylzincs to aldehydes, detailed in Chapter 5 (27), is accomplished with polymer catalysts containing DAIB, a camphor-derived auxiliary, and other chiral amino alcohols (28). Reactions that involve matrix isolation of the catalyst not only result in operational simplicity but also greatly facilitate understanding of the reaction mechanism. In solution, the catalytic chiral alkylzinc alkoxide derived from a dialkylzinc and DAIB exists primarily as dimer (27) however, when immobilized, its monomeric structure can be maintained. 

Me3SiN3, cat Ti(0-i-Pr)4, cat chiral diols or amino alcohols (enantioselective) Me3SiN3, cat TiQ2(0-i-Pr)2-dialkyl tartrate (enantioselective)... 

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