Asymmetric enolate with oxazolidinone chiral

Recently, a stereoselective synthesis of carbon-linked analogues of a- and 0-ga-lactoserine glycoconjugates has been reported using asymmetric enolate methodology [19]. The key step involved the electrophilic animation of a chiral oxazolidinone enolate with DTBAD. 

As above (eq 1), a major drawback of this reagent is the lack of a readily available enantiomer. There are many alternative methods for the enantioselective propionate aldol reaction. The most versatile chirally modified propionate enolates or equivalents are N-propionyl-2-oxazolidinones, a-siloxy ketones, boron enolates with chiral ligands, as well as tin enolates. Especially rewarding are new chiral Lewis acids for the asymmetric Mukaiyama reaction of 0-silyl ketene acetals. Most of these reactions afford s yw-aldols good methods for the anri-isomers have only become available recently. ... 

Other oxazolidinones have been used as chiral auxiliaries in asymmetric aldol reactions. Bomane derivatives 1.121 (X = O or S) and 1.122 are readily transformed into V-acyl derivatives. The reactions of their boron or titanium enolates with aldehydes give the same selectivities as Evans s reagents [426, 428, 429, 431, 436], iV-Acylimidazolidinones 1.131 and 1.132 [449, 1270] lead to similar results, but the selectivities observed are somewhat lower. 

Excellent levels of asymmetric induction in various carbon-carbon bond-forming reactions, such as alkylation, conjugate addition and aldol reactions, are possible using a suitable chiral enolate and an achiral electrophile under appropriate reaction conditions. A variety of chiral enolates have been investigated, the most common and useful synthetically being those with a chiral auxiliary attached to the carbonyl group. The 2-oxazolidinone group, introduced by Evans, has proved to be an efficient and popular chiral auxiUary. Both enantiomers of the product are... 

The utilization of a-amino acids and their derived 6-araino alcohols in asymmetric synthesis has been extensive. A number of procedures have been reported for the reduction of a variety of amino acid derivatives however, the direct reduction of a-am1no acids with borane has proven to be exceptionally convenient for laboratory-scale reactions. These reductions characteristically proceed in high yield with no perceptible racemization. The resulting p-amino alcohols can, in turn, be transformed into oxazolidinones, which have proven to be versatile chiral auxiliaries. Besides the highly diastereoselective aldol addition reactions, enolates of N-acyl oxazolidinones have been used in conjunction with asymmetric alkylations, halogenations, hydroxylations, acylations, and azide transfer processes, all of which proceed with excellent levels of stereoselectivity. 

Conversion of 2 to the highly crystalline oxazolidinone 3 with phosgene has been described by Thornton who has employed this substance as a chiral auxiliary in asymmetric aldol reactions of its N-propionyl derivative. Kelly has also used an oxazoline derived from 3 as a chiral auxiliary in asymmetric alkylation of a glycolate enolate. Oxazolidinone 3 has also been prepared from 2 with diethyl carbonate in the presence of potassium carbonate. The conversion of 2 to the oxazolidinone 3 is accomplished using triphosgene in this procedure because of the high toxicity of phosgene. 

In 1992 Ghosh and co-workers provided the first example of the utility of rigid cis-1 -amino-2-indanol-derived oxazolidinone 36 as the chiral auxiliary in the asymmetric. vv//-aldol reaction.60-61 Aldol condensation of the boron enolate of 37 with various aldehydes proceeded with complete diastereofacial selectivity. Effective removal and recovery of the chiral auxiliary was carried out under mild hydrolysis conditions (Scheme 24.6). As both enantiomers of the chiral auxiliary were readily available, both enantiomers of the. yyn-aldol could be prepared with equal asymmetric induction. 

The stereochemical outcome of these electrophilic additions is consistent with a transition state in which the metal chelates the oxazolidinone carbonyl and the enolate oxygen. Reaction with an electrophile would, therefore, occur at the less hindered diastereotopic face of the (Z)-enolate, away from the shielding methyl groups of the auxiliary (Figure 24.6). Because both enantiomers of oxazolidinone 108 are equally available, the direction of the asymmetric induction can be controlled by proper choice of the absolute stereochemistry of the chiral auxiliary.106... 

Analogous asymmetric, samarium Reformatsky reactions of chiral 3-bro-moacetyl-2-oxazolidinones have been described by Fukuzawa.140 For example, reduction of 124 with Sml2 generates a samarium enolate that then reacts with pivalaldehyde to give the a-unbranched (I-hydroxycarboximide 125 in 87% yield and in high diastereoisomeric excess (Scheme 5.89). The reaction is synthetically noteworthy as highly diastereoselective acetate aldol processes are difficult to achieve. Sm(III) ions are likely to play an important role in the... 

Phenylalanine-derived oxazolidinone has heen used in O Scheme 52 as a chiral auxiliary for as)rmmetric cross-aldolization (Evans-aldol reactions [277,278,279,280,281,282,283,284, 285]). The 6-deoxy-L-glucose derivative 155 has heen prepared by Crimmins and Long [286] starting with the condensation of acetaldehyde with the chlorotitanium enolate of O-methyl glycolyloxazohdinethione 150. A 5 1 mixture is obtained from which pure 151 is isolated by a single crystallization. After alcohol silylation and subsequent reductive removal of the amide, alcohol 152 is obtained. Swem oxidation of 152 and subsequent Homer-Wadsworth-Emmons olefination provides ene-ester 153. Sharpless asymmetric dihydroxylation provides diol 154 which was then converted into 155 (O Scheme 60) (see also [287]). 

An alternative to the bis-lactim ether approach is based on condensations of saturated five-membered heterocycles such as imidazolidinone (532) which can now be obtained in an optically pure state by a straightforward classical resolution/ The related oxazolidinone (533) has been obtained from methionine and used to prepare (R)-amino-acids [cf. (528) ] as well as the vinyl substituted derivatives(534) by oxidation and elimination of the sulphur group." Yet more general routes to chiral amino—acids have been reported using a variety of asymmetrically substituted ester enolate equivalents (535) in combination with the electrophilic nitrogen source di-t-butyl... 

The Evans oxazolidinones are one of the most important types of chiral auxiliary in organic synthesis. They were first reported in 1981 in the context of a diastereoselective aldol addition. The high levels of asymmetric induction associated with their use and the ease of preparation of these auxiliaries are two important reasons why they have become so firmly entrenched in organic synthesis. Oxazoh-dinones are readUy formed by the condensation of chiral, nonracemic 1,2-amino alcohols and a suitable carbonate species (e.g., diethylcarbonate and triphosgene)Once formed, the oxazolidinone (cf. 55, Scheme 7.30) may be iV-acylated by treatment with, for example, n-BuIi and an acid chloride. The resulting N-acyl oxazolidinones (cf. 202) have been used in a variety of enolate-based transformations. 

From a non-c ohydrate precursor, Davis and Qi achieved the asymmetric synthesis of 2-deoxy-2-fluoro- iylo-D-pyranose (9) (Figure 7) and 2-deoxy-2-fluoro-lyxo-L-pyranose (13). TTie key reaction was the highly diastereoselective fluorination of a chiral enolate using the electrophilic fluorinating agent, N-fluoro(benzenesulfonimide) (NFSi). In another study by Davis (14), the use of a chiral oxazolidinone adjuvant and fluorination with NFSi led to the chiral fluorohydrin 10 (>97% ee), which was oxidized by the Dess-Martin periodinane procedure to the non-racemic a- fluoroaldehyde 11 (94% ee). Conversion of 11 in four steps provided l,2,3-tri-0-acetyl-4-deoxy-4-fluoro-D-arabinopyranose (12) as a 1 1 mixture of anomers which could not be separated by flash chromatography. 

Evans has pioneered the use of carboximide-derived enolates in diastereo-selective enolate alkylation reactions [15, 82]. As discussed in subsequent chapters, N-acyl oxazolidinones (such as 114, 115, and 116) enjoy a unique position in asymmetric synthesis as chiral auxiliaries with wide applications in numerous mechanistically unrelated asymmetric transformations, among them aldol (Chapter 4), Diels-Alder (Chapter 17), enolate amination (Chapter 10), and conjugate addition (Chapter 12) reactions. Oxazolidinones 114 and 115 generally lead to Ca-substituted carboximide products in one dia-stereomeric series (cf 119, dr>99 1), while the complementary diastereo-meric adducts such as 122 dr =98 2) can be accessed through the use of oxazolidinone 116 (Scheme 3.18) [82]. 

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