Chiral auxiliaries lithium enolate aldol reaction

Besides their application in asymmetric alkylation, sultams can also be used as good chiral auxiliaries for asymmetric aldol reactions, and a / -product can be obtained with good selectivity. As can be seen in Scheme 3-14, reaction of the propionates derived from chiral auxiliary R -OH with LICA in THF affords the lithium enolates. Subsequent reaction with TBSC1 furnishes the 0-silyl ketene acetals 31, 33, and 35 with good yields.31 Upon reaction with TiCU complexes of an aldehyde, product /i-hydroxy carboxylates 32, 34, and 36 are obtained with high diastereoselectivity and good yield. Products from direct aldol reaction of the lithium enolate without conversion to the corresponding silyl ethers show no stereoselectivity.32... 

The foregoing results clearly constitute an encouraging lead, and represent the best that has yet been done with chiral auxiliaries for lithium enolate aldol reactions. Although the chiral auxiliary is not covalently attached to either reactant, it is still used stoichiometrically. Furthermore, the process has only been demonstrated with the aldol reaction in equation (133). It will be interesting to see if the efficacy of this method will extend to other enolates and aldehydes. 

The enolates of other carbonyl compounds can be used in mixed aldol reactions. Extensive use has been made of the enolates of esters, thiol esters, amides, and imides, including several that serve as chiral auxiliaries. The methods for formation of these enolates are similar to those for ketones. Lithium, boron, titanium, and tin derivatives have all been widely used. The silyl ethers of ester enolates, which are called silyl ketene acetals, show reactivity that is analogous to silyl enol ethers and are covalent equivalents of ester enolates. The silyl thioketene acetal derivatives of thiol esters are also useful. The reactions of these enolate equivalents are discussed in Section 2.1.4. 

In Step D another thiazoline chiral auxiliary, also derived from cysteine, was used to achieve double stereodifferentiation in an aldol addition. A tin enolate was used. The stereoselectivity of this reaction parallels that of aldol reactions carried out with lithium or boron enolates. After the configuration of all the centers was established, the synthesis proceeded to P-D lactone by functional group modifications. 

As with the above pyrrolidine, proline-type chiral auxiliaries also show different behaviors toward zirconium or lithium enolate mediated aldol reactions. Evans found that lithium enolates derived from prolinol amides exhibit excellent diastereofacial selectivities in alkylation reactions (see Section 2.2.32), while the lithium enolates of proline amides are unsuccessful in aldol condensations. Effective chiral reagents were zirconium enolates, which can be obtained from the corresponding lithium enolates via metal exchange with Cp2ZrCl2. For example, excellent levels of asymmetric induction in the aldol process with synj anti selectivity of 96-98% and diastereofacial selectivity of 50-200 116a can be achieved in the Zr-enolate-mediated aldol reaction (see Scheme 3-10). 

Covalently bonded chiral auxiliaries readily induce high stereoselectivity for propionate enolates, while the case of acetate enolates has proved to be difficult. Alkylation of carbonyl compound with a novel cyclopentadienyl titanium carbohydrate complex has been found to give high stereoselectivity,44 and a variety of ft-hydroxyl carboxylic acids are accessible with 90-95% optical yields. This compound was also tested in enantioselective aldol reactions. Transmetalation of the relatively stable lithium enolate of t-butyl acetate with chloro(cyclopentadienyl)-bis(l,2 5,6-di-<9-isopropylidene-a-D-glucofuranose-3-0-yl)titanate provided the titanium enolate 66. Reaction of 66 with aldehydes gave -hydroxy esters in high ee (Scheme 3-23). 

Darzens reaction of (-)-8-phenylmethyl a-chloroacetate (and a-bromoacetate) with various ketones (Scheme 2) yields ctT-glycidic esters (28) with high geometric and diastereofacial selectivity which can be explained in terms of both open-chain or non-chelated antiperiplanar transition state models for the initial aldol-type reaction the ketone approaches the Si-f ce of the Z-enolate such that the phenyl ring of the chiral auxiliary and the enolate portion are face-to-face. Aza-Darzens condensation reaction of iV-benzylideneaniline has also been studied. Kinetically controlled base-promoted lithiation of 3,3-diphenylpropiomesitylene results in Z enolate ratios in the range 94 6 (lithium diisopropylamide) to 50 50 (BuLi), depending on the choice of solvent and temperature. ... 

Asymmetric aldol reactions5 (11, 379-380). The lithium enolate of the N-propionyloxazolidinone (1) derived from L-valine reacts with aldehydes with low syn vs. anti-selectivity, but with fair diastereofacial selectivity attributable to chelation. Transmetallation of the lithium enolate with ClTi(0-i-Pr)3 (excess) provides a titanium enolate, which reacts with aldehydes to form mainly the syn-aldol resulting from chelation, the diastereomer of the aldol obtained from reactions of the boron enolate (11, 379-380). The reversal of stereocontrol is a result of chelation in the titanium reaction, which is not possible with boron enolates. This difference is of practical value, since it can result in products of different configuration from the same chiral auxiliary. 

Early investigations of asymmetric aldol reactions with chiral carbohydrate auxliliaries were carried out by Heathcock [152] and Bandraege [159], but often only low stereoselectivities were observed. In additional studies. Banks et al. [73] used oxazinone auxiliaries for aldol reactions, which had been employed for other asymmetric reactions. The lithium enolate of the A-acylated oxazinone 226 reacted with benzaldehyde, furnishing exclusively the iyn-aldols 227A and 227B in a ratio of 10 1 (Scheme 10.76). 

A "heterocyclic" strategy used an oxazolidone ring as a protected carboxyl (an amide) which also served as a chiral auxiliary. Treatment of 6.127 with a boron triflate, for example, gave boron enolate reagent 6.128 in situ, and it reacted with N-Boc leucinal to form 6.129. Boron enolates have been used in many syntheses as an alternative to lithium or sodium enolate in Aldol reactions.S7 Hydrogcnolysis of the methylthio moiety gave a methylene moiety and treatment of the amide auxiliary with base gave 6.95 (24% overall yield). 

The chiral auxiliary is the oxazolidinone (24) derived from IS,2R) norephedrine. Acylation with propionyl chloride gives (25) and this is deprotonated to afford exclusively the internally chelated Z-enolate, which reacts with methallyl iodide from the face opposite the methyl and phenyl groups of the auxiliary. The product (26), a 97 3 mixture of diastereomers, is purified to a ratio of better than 500 1. Reductive removal of the auxiliary and careful oxidation of the primary alcohol under non-racemising conditions affords the chiral (5)-aldehyde (27). This in turn is reacted with the boron enolate of (25), which furnishes with remarkable selectivity the u aldol product (28). The reason for the choice of boron rather than lithium is to invert the facial selectivity of the reaction— the enolate is no longer constrained to be planar by internal chelation and rotates in order to place the bulky dibutyl borinyl group on the opposite side to the methyl and phenyl ... 

Typically, in these aldol additions sy -aldol adducts are formed, in which the chiral auxiliary induces the absolute configuration. The sultam methodology by Oppolzer is particularly useful as both enantiomeric aldols may be generated from the same auxiliary, by adjusting the reaction conditions (Scheme 3.69). Thus, in route A the enolborinate is generated and adduct 353 is formed [113]. If, however, in route B the lithium or the stannyl enolates are used the predominant aldol adduct is 355. The overaD selectivity of route B is lower than the one of route A. In addition to the formation of the syn-adducts 353 and 355, the two anti-diastereomers 354 and 356 are observed in small quantities for the lithium enolate whereas 354 is suppressed by using a tin enolate. 

Another auxiliary that became well known in enolate chemistry is chiral acyl iron complexes for alkylation, aldol reactions, and conjugate additions indeed, so-called Davies-Liebeskind enolates [60] can be generated either by deprotonation of alkanoyl complexes 124a or conjugate addition of strong nucleophiles like alkyllithium compounds or lithium amides to alkenoyl complexes 127. 

Later, Yamamoto and coworkers developed the axially chiral ester 183 for asymmetric acetate aldol additions. After formation of the lithium enolate with LDA, the reaction with various aldehydes yielded P-hydroxy esters 184 in very high diastereoselectivity. It was shown, for two adducts, that a nearly quantitative saponification leads to P-hydroxy carboxylic acids 176 and liberates phenol 185 in nearly quantitative yield and undiminished optical purity (Scheme 4.40) [100]. The authors discuss a twist-boat as well as an open transition state for rationalizing the preferred Re-face attack to the aldehyde, observed with (R,R)-configured acetate 183. Yamamoto s procedure is impressive because of its stereoselectivity, but one has to be aware that the chiral auxiliary 185 is by far not as readily accessible as others also enabling the asymmetric acetate aldol addition. 

Compared to the aldol addition, the stereochemical scheme is complicated by the fact that the Michael acceptor may not always and not exclusively adopt the -configuration as shown in 421 but also as Z-diastereomer. The effect of this isomerism has been addressed in a fundamental contribution of Corey and Peterson, which is also one of the first applications of an auxiliary-based stereoselective Michael addition. The chiral lithium enolate 425 that was generated from the propionic ester 424 of phenylmenthol by deprotonation was assumed to adopt the enolate in fcr /is-configuration, in accordance with Ireland s model (cf Section 2.1). The reaction of the enolate with ( )- and (Z)-methyl crotonate led to the Michael products sy/i-426 and a f/-427, respectively. The Michael addition to ( )-crotonate was faster at low temperatures than that of the (Z)-diastereomer and provided higher chemical yields as well as syw-anti-selectivity and induced stereoselectivity. A closed, eight-membered transition state model 428 has been proposed that plausibly explains the opposite stereochemical outcome depending on the double-bond configuration of the Michael acceptor. As the rear side is shielded by the bulky 2-phenyl-2-propyl substituent, the attack of both croto-nates occurs at the Si-face of the enolate 425. Whereas Si-face of ( )-crotonate is selected for the addition of the enolate, the attack to (Z)-crotonate occurs predominantly from the e-face (Scheme 4.92) [206]. 

---