Aldol reaction using chiral enolates

SCHEME 2.115 Aldol reaction using chiral enolates. 

Diastereoselective Aldol Reactions Using Chiral Enolates Although the approach that uses chiral auxiliaries or other elements of stoichiometric chiral information is not as elegant as asymmetric catalysis, it is highly practical. At present, the boron-mediated aldol reaction of enolates 112 and 115 with aldehydes giving the syn aldol products 113 and 116 constimtes one of the best C C bond forming methods (Scheme 10.26). ... 

The situation is complex. In another study we examined the cyclization of compound 54 catalyzed by cyclodextrin bis-imidazoles [140]. This dialdehyde can perform the intramolecular aldol reaction using the enol of either aldehyde to add to the other aldehyde, forming either 55 or 56. In solution with simple buffer catalysis both compounds are formed almost randomly, but with the A,B isomer 46 of the bis-imidazole cyclodextrin there was a 97 % preference for product 56. This is consistent with the previous findings that the catalyst promotes enolization near the bound phenyl ring, but in this case the cyclization is most selective with the A,B isomer 46, not the A,D that we saw previously. Again the enolization is reversible, and the selectivity reflects the addition of an enol to an aldehyde group. The predominant product is a mixture of two stereoisomers, 56A and 56B. Both were formed, and were racemic despite the chirality of the cyclodextrin ring. 

The BINAP silver(I) complex can be further applied as a chiral catalyst in the asymmetric aldol reaction. Although numerous successful methods have been developed for catalytic asymmetric aldol reaction, most are the chiral Lewis acid-catalyzed Mukaiyama aldol reactions using silyl enol ethers or ketene silyl acetals [32] and there has been no report which includes enol stannanes. Yanagisawa, Yamamoto, and their colleagues found the first example of catalytic enantioselective aldol addition of tributyltin enolates 74 to aldehydes employing BINAP silver(I) complex as a catalyst (Sch. 19) [33]. 

The Evans aldol reaction using chiral p-keto imide 23 as a dipropionate building block is also very effective for the construction of polypropionate segments in polyoxomacrolides (Scheme 2) [8]. The diastereoselective aldol reaction of 23 via different metal enolates (Ti, Sn, and B enolates) afforded three kind of aldols, syn-syn-24, anti-syn-25, and anti-anti-26, with high diastereoselectivity, respectively. The subsequent stereoselective reduction of the resulting p-hydroxy ketones 24-26 provides various types of dipropionate units. Based on this strategy, the... 

The aldol reaction using chiral a-oxygenated ketones proceeds in a diastereose-lective manner (Scheme 3) (Z)-boron enolate 28 derived from benzyloxy ketone 27 afforded sy -aldol 29 via chelation control, while benzoyloxy ketone 30 afforded anft-aldol 32 via ( )-enolate 31 through a nonchelation transition state [9]. 

These findings brought about extensive studies of asymmetric aldol reactions using silyl enol ethers of thiol esters that employed other chiral diamines [24] or organometals such as Cu [25], Zr [26], Ti [27], B [28], Sc [29], and Pr... 

Asymmetric Aldol Reactions Using Chiral Boron Enolates... 

Chiral Metal Enolates in Aldol Reaction A general overview on common acetate aldol reaction using chiral metal enolates is given in Scheme 2.115. Both Masamune [18] and Corey [19] in their acetate aldol reaction use C2-symmetric boron complexes and as the acetate building block thio esters. Transformations with aldehydes usually provide enantiomeric ratios between 92 8 and 96 4 in good yields. More commonly used nowadays are Paterson s, Duthaler s, and Braun s acetate strategies. 

Evans and co-workers have established the boron-mediated stereoselective aldol reaction using chiral (3-alkoxyketones (Scheme 8.19). The boron enolate... 

These examples and those in Scheme 2.6 illustrate the key variables that determine the stereochemical outcome of aldol addition reactions using chiral auxiliaries. The first element that has to be taken into account is the configuration of the ring system that is used to establish steric differentiation. Then the nature of the TS, whether it is acyclic, cyclic, or chelated must be considered. Generally for boron enolates, reaction proceeds through a cyclic but nonchelated TS. With boron enolates, excess Lewis acid can favor an acyclic TS by coordination with the carbonyl electrophile. Titanium enolates appear to be somewhat variable but can be shifted to chelated TSs by use of excess reagent and by auxiliaries such as oxazolidine-2-thiones that enhance the tendency to chelation. Ultimately, all of the factors play a role in determining which TS is favored. 

Sn(OTf)2 can function as a catalyst for aldol reactions, allylations, and cyanations asymmetric versions of these reactions have also been reported. Diastereoselective and enantioselective aldol reactions of aldehydes with silyl enol ethers using Sn(OTf)2 and a chiral amine have been reported (Scheme SO) 338 33 5 A proposed active complex is shown in the scheme. Catalytic asymmetric aldol reactions using Sn(OTf)2, a chiral diamine, and tin(II) oxide have been developed.340 Tin(II) oxide is assumed to prevent achiral reaction pathway by weakening the Lewis acidity of Me3SiOTf, which is formed during the reaction. 

Shibasaki et al. also developed catalytic reactions of copper, some of which can be applied to catalytic asymmetric reactions. Catalytic aldol reactions of silicon enolates to ketones proceed using catalytic amounts of CuF (2.5 mol%) and a stoichiometric amount of (EtO)3SiF (120 mol%) (Scheme 104).500 Enantioselective alkenylation catalyzed by a complex derived from CuF and a chiral diphosphine ligand 237 is shown in Scheme 105.501 Catalytic cyanomethyla-tion by using TMSCH2CN was also reported, as shown in Scheme 106.502... 

Besides the silyl enolate-mediated aldol reactions, organotin(IY) enolates are also versatile nucleophiles toward various aldehydes in the absence or presence of Lewis acid.60 However, this reaction requires a stoichiometric amount of the toxic trialkyl tin compound, which may limit its application. Yanagisawa et al.61 found that in the presence of one equivalent of methanol, the aldol reaction of an aldehyde with a cyclohexenol trichloroacetate proceeds readily at 20°C, providing the aldol product with more than 70% yield. They thus carried out the asymmetric version of this reaction using a BINAP silver(I) complex as chiral catalyst (Scheme 3-34). As shown in Table 3-8, the Sn(IY)-mediated aldol reaction results in a good diastereoselectivity (,anti/syn ratio) and also high enantioselectivity for the major component. 

Perlmutter used an oxymercuration/demercuration of a y-hydroxy alkene as the key transformation in an enantioselective synthesis of the C(8 ) epimeric smaller fragment of lb (and many more pamamycin homologs cf. Fig. 1) [36]. Preparation of substrate 164 for the crucial cyclization event commenced with silylation and reduction of hydroxy ester 158 (85-89% ee) [37] to give aldehyde 159, which was converted to alkenal 162 by (Z)-selective olefination with ylide 160 (dr=89 l 1) and another diisobutylaluminum hydride reduction (Scheme 22). An Oppolzer aldol reaction with boron enolate 163 then provided 164 as the major product. Upon successive treatment of 164 with mercury(II) acetate and sodium chloride, organomercurial compound 165 and a second minor diastereomer (dr=6 l) were formed, which could be easily separated. Reductive demercuration, hydrolytic cleavage of the chiral auxiliary, methyl ester formation, and desilylation eventually led to 166, the C(8 ) epimer of the... 

Although in the recent years the stereochemical control of aldol condensations has reached a level of efficiency which allows enantioselective syntheses of very complex compounds containing many asymmetric centres, the situation is still far from what one would consider "ideal". In the first place, the requirement of a substituent at the a-position of the enolate in order to achieve good stereoselection is a limitation which, however, can be overcome by using temporary bulky groups (such as alkylthio ethers, for instance). On the other hand, the ( )-enolates, which are necessary for the preparation of 2,3-anti aldols, are not so easily prepared as the (Z)-enolates and furthermore, they do not show selectivities as good as in the case of the (Z)-enolates. Finally, although elements other than boron -such as zirconium [30] and titanium [31]- have been also used succesfully much work remains to be done in the area of catalysis. In this context, the work of Mukaiyama and Kobayashi [32a,b,c] on asymmetric aldol reactions of silyl enol ethers with aldehydes promoted by tributyltin fluoride and a chiral diamine coordinated to tin(II) triflate... 

A similar enantiomer-selective activation has been observed for aldol " and hetero-Diels-Alder reactions.Asymmetric activation of (R)-9 by (/f)-BINOL is also effective in giving higher enantioselectivity (97% ee) than those by the parent (R)-9 (91% ee) in the aldol reaction of silyl enol ethers (Scheme 8.12a). Asymmetric activation of R)-9 by (/f)-BINOL is the key to provide higher enantioselectivity (84% ee) than those obtained by (R)-9 (5% ee) in the hetero-Diels-Alder reaction with Danishefsky s diene (Scheme 8.12b). Activation with (/ )-6-Br-BINOL gives lower yield (25%) and enantioselectivity (43% ee) than the one using (/f)-BINOL (50%, 84% ee). One can see that not only steric but also electronic factors are important in a chiral activator. 

Bismuth triflate has been reported by Dubac as an efficient catalyst for the Mukaiyama aldol reaction with silyl enol ethers [27] and was recently used with a chiral ligand, as reported by Kobayashi in an elegant hydroxymethylation reaction... 

The aldol reaction of an enolate or enolate equivalent with an imine is referred to as the Mannich-type reaction. Asymmetric Mannich-type reactions provide useful routes for the synthesis of enantiomerically enriched p-amino acid derivatives, which are versatile chiral building blocks for the synthesis of nitrogen-containing biologically important compounds [23]. Despite the enormous progress made in asymmetric aldol reactions [24], the corresponding asymmet-... 

Carbonyl Addition Diethylzinc has been added to benzaldehyde at room temperature in the presence of an ephedra-derived chiral quat (8) to give optically active secondary alcohols, a case in which the chiral catalyst affords a much higher enantioselectivity in the solid state than in solution (47 to 48, Scheme 10.6) [30]. Asymmetric trifluoromethylation of aldehydes and ketones (49 to 50, Scheme 10.6 [31]) is accomplished with trifluoromethyl-trimethylsilane, catalyzed by a quaternary ammonium fluoride (3d). Catalyst 3d was first used by the Shioiri group for catalytic asymmetric aldol reactions from silyl enol ethers 51 or 54 (Scheme 10.6) [32]. Various other 1,2-carbonyl additions [33] and aldol reactions [34] have been reported. 

Aldol reactions using a quaternary chinchona alkaloid-based ammonium salt as orga-nocatalyst Several quaternary ammonium salts derived from cinchona alkaloids have proven to be excellent organocatalysts for asymmetric nucleophilic substitutions, Michael reactions and other syntheses. As described in more detail in, e.g., Chapters 3 and 4, those salts act as chiral phase-transfer catalysts. It is, therefore, not surprising that catalysts of type 31 have been also applied in the asymmetric aldol reaction [65, 66], The aldol reactions were performed with the aromatic enolate 30a and benzaldehyde in the presence of ammonium fluoride salts derived from cinchonidine and cinchonine, respectively, as a phase-transfer catalyst (10 mol%). For example, in the presence of the cinchonine-derived catalyst 31 the desired product (S)-32a was formed in 65% yield (Scheme 6.16). The enantioselectivity, however, was low (39% ee) [65],... 

Stereoselective syntheses of several unnatural amino acids were required to initiate this work. Evans group used asymmetric reactions of chiral enolates to generate these starting materials, as illustrated in the diagram shown below. In this particular example, an isothiocyanate functionality traps the alcohol of an aldol product giving a thiooxazolidinone that provides O- and N-protection in subsequent steps. 

It has been demonstrated that optically active oxetanes can be formed from oxazolidinone 92, a crotonic acid moiety functionalized with Evans chiral auxiliary (Scheme 18) <1997JOC5048>. In this two-step aldol-cyclization sequence, the use of 92 in a deconjugative aldol reaction, with boron enolates and ethanal, led to formation of the syn-aldol 93. This product was then converted to the corresponding oxetanes, 94a and 94b, via a cyclization with iodine and sodium hydrogencarbonate. This reaction sequence was explored with other aldehydes to yield optically active oxetanes in similar yields. Unlike previous experiments using the methyl ester of crotonic acid, in an analogous reaction sequence rather than the oxazolidinone, there was no competing THF formation. 

In 1995, Boeckman et al. disclosed a highly diastereoselective aldol reaction using the ligand 79 derived from chiral bicyclic lactam28 (Scheme 2.1z). The imide 80, readily prepared from bicyclic lactam 79 and propionyl chloride, was converted to the boron Z-enolate, which was then treated with a representative series of aldehydes at -40° C for 48 hours. The levels of diastereoselectivity observed in reactions of boron enolate derived from 80 are comparable to those... 

On the other hand, the condensation of Gamer s aldehyde574 with the non-chiral lithium enolate of diethylacetamide in non-chelating conditions occurs preferentially on the 57-face with a moderate 37% d.e. The same reaction using the enolate of (R.R)- or (5,5)-pseudoephedrine acetamides resulted in identical anti aldol adducts, but with an amplification of the face recognition of the aldehyde for the matched (R, W )-pscudoephedrine (d.e. = 96%). On the other hand, the mismatched (5,5)-pseudoephedrine gave only 12% d.e. (Scheme 120)575. 

Catalytic versions of the asymmetric aldol reaction using simple lithium enolates and substoichiometric amounts of a chiral catalyst are rare611. The bimetallic system proposed by Shibasaki and coworkers deserve to be mentioned at this point. The combination of a... 

Highly diastereoselective acetate aldol additions using chlorotitanium enolates of mesityl-substituted JV-acetylthiazolidinethione 136 has been documented <07OL149>. These aldol reactions proceed in high yields and diastereoselectivities (94/6 to 98/2) for aliphatic, aromatic, and a,P-unsaturated aldehydes. Compound 136 also undergoes double diastereoselective aldol additions with chiral aldehyde 139 to give adduct 140 in high yields. 

Optically active 1,2-diol units are often observed in nature as carbohydrates, macrolides or polyethers, etc. Several excellent asymmetric dihydroxylation reactions of olefins using osmium tetroxide with chiral ligands have been developed to give the optically active 1,2-diol units with high enantioselectivities. However, there still remain some problems, for example, preparation of the optically active anti-1,2-diols and so on. The asymmetric aldol reaction of an enol silyl ether derived from a-benzyloxy thioester with aldehydes was developed in order to introduce two hydroxyl groups simultaneously with stereoselective carbon-carbon bond formation by using the chiral tin(II) Lewis acid. For example, various optically active anti-a,p-dihydroxy thioester derivatives are obtained in good yields with excellent diastereo-... 

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