Aldol oxazolidinone-based

The approach for the enantioselective aldol reaction based on oxazolidinones like 22 and 23 is called Evans asymmetric aldol reaction.14 Conversion of an oxazolidinone amide into the corresponding lithium or boron enolates yields the Z-stereoisomers exclusively. Reaction of the Z-enolate 24 and the carbonyl compound 6 proceeds via the cyclic transition state 25, in which the oxazolidinone carbonyl oxygen and both ring oxygens have an anti conformation because of dipole interactions. The back of the enolate is shielded by the benzyl group thus the aldehyde forms the six-membered transition state 25 by approaching from the front with the larger carbonyl substituent in pseudoequatorial position. The... 

Aldol reactions using chiral auxiliaries are popular as the stereochemical outcome is usually highly predictable and, as such, they provide a reliable method for the incorporation of adjacent stereocenters. The oxazolidinone-based imides 36 and (ent)-36 are the most commonly employed, and these lead to syn aldol products with high levels of stereocontrol [20]. The reaction can be extended to include a variety of a-heteroatom functionality as in 37 (Scheme 9-13) [21]. Numerous examples of the use of these auxiliaries in the synthesis of polypropionate natural products have been reported. Many related auxiliaries are also available and the camphor-based sultam 38 is notable [22]. 

Miscellanea A methodology to prepare a-substituted-P-hydroxy acids and esters has been introduced in solid phase based on an Evans oxazolidinone-based linker to produce enantiospecifk aldol condensations (Figure 15.4). Acids and esters were released by treatment with LiOH and H202 in THF (at -20 °C) or NaOMe in THF, respectively [58, 59], Diels-Alder adducts of oxazolidinone-bound crotonates have also been detached with LiOCH2Ph [60],... 

Scheme 4-6 Evans oxazolidinone-based chiral auxiliaries in diastereoselective aldol...

In the first formal asymmetric synthesis of phorbol, a tigliane diterpene, Wender and co-workers utilized a chiral oxazolidinone-based asymmetric aldol reaction to produce chiral alcohol 43, a non-Evans syn product as a single diastereomer in 96% yield. ... 

Asymmetric aldol reactions utilizing chiral auxiliaries or templates have emerged as one of the most reliable methods in organic synthesis. Both syn-and anti-selective aldol reactions have been developed over the years. The field of asymmetric syn aldol reactions has been largely advanced by Evans since his development of dibutylboron enolate aldol chemistry based on amino acid-derived chiral oxazolidinones. This method requires expensive dibutylboron trifiate, hosvever, and the amino acid-derived chiral auxiliary is only readily available in one enantiomer and thus only provides one enantiomer of the syn aldol. Several methods developed on the basis of titanium enolates provide convenient access to both Evans and non-Evans syn aldol products. 

Evans and coworkers also brought about ti-selective aldol additions based upon Af-propionyl oxazolidinones and thiazolidinethiones, which is surprising in view of the fact that these auxiliaries seems to be predestined for providing sy -selectivity [116]. However, the soft enolization of oxazolidinone 73 with magnesium chloride in the presence of a tertiary amine and chlorotrimethylsUane induced an addition to various aromatic and a,P-unsaturated aldehydes that led to a ti-configured sUyl-protected aldols 225 in a highly diastereoselective manner. 

Reaction progress kinetic analysis offers a reliable alternative method to assess the stability of the active catalyst concentration, again based on our concept of excess [e]. In contrast to our different excess experiments described above, now we carry out a set of experiments at the same value of excess [ej. We consider again the proline-mediated aldol reaction shown in Scheme 50.1. Under reaction conditions, the proline catalyst can undergo side reactions with aldehydes to form inactive cyclic species called oxazolidinones, effectively decreasing the active catalyst concentration. It has recently been shown that addition of small amounts of water to the reaction mixture can eliminate this catalyst deactivation. Reaction progress kinetic analysis of experiments carried out at the same excess [e] can be used to confirm the deactivation of proline in the absence of added water as well to demonstrate that the proline concentration remains constant when water is present. 

Stereochemical Control Through Chiral Auxiliaries. Another approach to control of stereochemistry is installation of a chiral auxiliary, which can achieve a high degree of facial selectivity.124 A very useful method for enantioselective aldol reactions is based on the oxazolidinones 10,11, and 12. These compounds are available in enantiomerically pure form and can be used to obtain either enantiomer of the desired product. 

The preceding reactions illustrate control of stereochemistry by aldehyde substituents. Substantial effort has also been devoted to use of chiral auxiliaries and chiral catalysts to effect enantioselective aldol reactions.71 72 Avery useful approach for enantioselective aldol condensations has been based on the oxazolidinones 1-3, which are readily available in enantiomerically pure form. 

Section A.5). Indeed, three enantiomeric pairs of 2-oxazolidinones have been commercially available since 1991. Enantiomerically pure 4-phenyl-2-oxazolidinone has likewise been prepared from / -aminobenzeneethanol (phenylglycinol)64. Base-catalyzed acylation of the enantiomerically pure 2-oxazolidinones with an appropriate acyl chloride gives the desired 3-acyl-2-oxazolidinones 3, 6 and 9 which have been used extensively in highly diastereoselective reactions of various types such as alkylations, aldol reactions (see Section D.l.3.4.2.4), hydrox-ylations (see Section D.4.1), aminations (see Section D.7.1) and Diels-Alder reactions (see Section D. 1.6.1.6) alkylation giving products with induced chirality in the a-position. 

Di-n-butylboryl Trifluoromethanesulfomte with a tertiary amine also provides the (Z)-enolates of chiral acyl oxazolidinones in >100 1 selectivity for use in subsequent aldol additions With Triethylamine, Diisopropylethylamine (Hunig s base), or 2,6-Lutidine the order of addition is of no consequence to enolization." Triethylamine has traditionally seen the greatest utilization in these reactions based upon cost considerations however, with certain sensitive aldehyde substrates, lutidine provides milder reaction conditions." ... 

Chiral oxazolidinone auxiliaries based on D-glucose were used for aldol reactions by Koell et al. [160]. The highest select vities were observed with auxiliaries equipped with the pivaloyl protecting group. The pivaloylated oxazolidinone 228 was transformed into the boron enolate according to the procedure of Evans [161] and subsequently reacted with aliphatic and aromatic aldehydes. The best results were obtained with isobutyric aldehyde (Scheme 10.77). The syn-dldo 229 was formed in 16-fold excess over the a/i Z-diastereomer and with an acceptable yield of 59%. The authors explain the stereoselectivity by a chair-like transition state according to Zimmermann-Traxler. The electrophile approaches at the less hindered r -face of the (Z)-configured enolate double bond. For A -phenacetyl substituents, an inversed stereoselectivity was observed as described above for these oxazolidinone auxiliaries. 

The enolates of other carbonyl compounds can be used in mixed aldol condensations. Extensive use has been made of the enolates of esters, thioesters, and amides. Of particular importance are several modified amides, such as those derived from oxazolidinones, that can be used as chiral auxiliaries. The methods for formation of these enolates are similar to those for ketones. Lithium, boron, tin, and titanium derivatives have all been used. Because of their usefulness in aldol additions and other synthetic methods (see especially Section 6.4.2.3, Part B), there has been a good deal of interest in the factors that control the stereoselectivity of enolate formation from esters. For simple esters such as ethyl propanoate, the E-enolate is preferred under kinetic conditions using a strong base such as EDA in THE solution. Inclusion of a... 

The methods that we have just discussed can be used to control the ratio of syn and anti diastereomeric products. It is often desired to also control the reaction to provide a specific enantiomer. Nearby stereocenters in either the carbonyl compound or the enolate can impose facial selectivity. Chiral auxiliaries can achieve the same effect. Finally, use of chiral Lewis acids as catalysts can also achieve enantioselectivity. Much effort has also been devoted to the use of chiral auxiliaries and chiral catalysts to effect enantioselective aldol reactions." A very useful approach for enantioselective aldol additions is based on the oxazolidinones 4,5, and 6. 

The regio- and the stereoselectivity of proline-catalyzed a-electrophilic substitution of carbonyl compounds can therefore be successfully explained by the oxazolidinone model, although the diastereoselectivity of the aldol and Mannich reactions was not taken into account in Seebach s discussion. Moreover, the model also could explain the autoinductive effects observed by Blackmond in the proline-catalyzed nitroso aldol and a-amination reactions of aldehydes [29, 31], by simply assuming that the oxazolidinone product acts as a base in the rate-determining enamine formation step. Kinetic resolution of proline, leading to chirality amplification effects, would be accounted for by the greater thermodynamic stability of the matched oxazolidinone product. In fact, the formation of Seebach s oxazolidi-nones, rather than enamines or iminium ion intermediates, from ketones and proline in DMSO solution had been described by List et al. in 2004 [23], but they concluded that this was a parasitic equilibrium leading to an unproductive intermediate. On the other hand, the product oxazolidinone in the proline-catalyzed a-amination of... 

A very useful approach for enantioselective aldol condensations has been based on the oxazolidinones 1 and 2. Both compounds are readily available in enantiomeri-cally pure form. 

In any treatment of auxiliary-based alkylations (as well as aldol additions, enolate oxidations, Mannich and Michael reactions), clearly, the carboximide enolates pioneered by the group of Evans are the center of attention. Developed in the early 1980, JV-acyl derivatives of oxazolidinones 45-47 (Scheme 4.9) became the epitomes of chiral auxiliaries [7,28] with countless applications in natural products and drug syntheses. The enantiomeric oxazolidinones (S)- and (R)-47 derived from the corresponding enantiomer of phenylalanine have the advantage that, when used for various transformations, the corresponding products have a higher tendency to crystallization and were shortly later added [29] to this collection of classics. 

An alternative to the boron-mediated aldol addition of oxazolidinone 210 was developed also by Evans and coworkers by using the direct formation of chlorotitanium enolates that were generated by treatment with titanium tetrachloride in the presence of Hiinig s base or TMEDA. The stereochemical... 

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