Evans aldol reaction anti aldols

Non-Evans Aldol Reactions. Either the syn- or onri-aldol adducts may be obtained from this family of imide-derived eno-lates, depending upon the specific conditions employed for the reaction. Although the illustrated boron enolate affords the illustrated jyn-aldol adduct in high diastereoselectivity, the addition reactions between this enolate and Lewis acid-coordinated aldehydes afford different stereochemical outcomes depending on the Lewis acid employed (eq 35). Open transition states have been proposed for the Diethylaluminum Chloride mediated, anti-selective reaction. These anfi-aldol reactions have been used in kinetic resolutions of 2-phenylthio aldehydes. ... 

The observed stereoselectivity in the Evans aldol reaction can be explained by the ZImmerman-Traxler transition state model. There are eight possible transition states, four of which would lead to the anti aldol product. These, however, are disfavored due to the presence of unfavorable 1,3-diaxial interactions (not depicted below). The possible transition states leading to the syn aldol product are shown below. The preferred transition state leading to the product is transition state A, where the dipoles of the enolate oxygen and the carbonyl group are opposed, and there is the least number of unfavored steric interactions. 

Stevastelins are depsipeptides exhibiting immunosuppressant activity. The first total synthesis of stevastelin B was described by Y. Yamamoto and co-workers. To construct four consecutive stereocenters, the Evans aldol reaction and the Roush asymmetric allylation were utilized. In the allylation step, the authors used (S,S)-diisopropyltartrate-derived ( )-crotyl boronate. The anti homoallylic alcohol product formed as the only diastereomer. 

Though either enantiomer of a yyn-aldol can be made by using the right auxiliary in an Evans aldol reaction the anti aldols cannot be made this way. The addition of a Lewis acid catalyst transforms the situation.13 Using the valine-derived chiral auxiliary 89, the same Z-boron enolate 111 is used but the aldehyde is added in the presence of a threefold excess of the Lewis acid Et2AlCl. The product is predominantly one enantiomer of an anh-aldol 112. 

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... 

Chiral Auxiliaries in Aldol Reaction Asymmetric aldol reactions ntilizing chiral auxiliaries 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 i yn-aldol reactions has been largely advanced by Evans since his development of dibntylboron enolate aldol chemistry based on amino acid-derived chiral oxazolidinones (Scheme 2.109) [9]. 

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). 

Among chiral auxiliaries, l,3-oxazolidine-2-thiones (OZTs) have attracted important interest thanks to there various applications in different synthetic transformations. These simple structures, directly related to the well-documented Evans oxazolidinones, have been explored in asymmetric Diels-Alder reactions and asymmetric alkylations (7V-enoyl derivatives), but mainly in condensation of their 7V-acyl derivatives on aldehydes. Those have shown interesting characteristics in anti-selective aldol reactions or combined asymmetric addition. Normally, the use of chiral auxiliaries which can accomplish chirality transfer with a predictable stereochemistry on new generated stereogenic centers, are indispensable in asymmetric synthesis. The use of OZTs as chiral copula has proven efficient and especially useful for a large number of stereoselective reactions. In addition, OZT heterocycles are helpful synthons that can be specifically functionalized. 

Evans also investigated the aldol condensation between methyl pyruvate 151 and several different substituted enol ethers 152, again using bu-box 3 and copper(II) triflate. These reactions achieved selectivities up to 98 2 (syn/anti) with syn ee up to 98% and yields up to 96% (Table 9.27, Fig. 9.47h). " ... 

Recently, Evans has reported diastereoselective magnesium hahde-catalyzed anti-aldol reactions of chiral Af-acyloxazolidinones 88 (equation 115) and A-acylthiazolidine-thiones 90 (equation 116) . ... 

The Evans-Tischenko Reaction generally requires a P-hydroxyketone (developed from an Aldol reaction) to react with an aldehyde. The resulting glycol monoester will be characterized as having high anti-selectivity. 

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... 

In the synthesis of RK-397 (18), Denmark and Fujimori prepared an anft -diol using the Evans-Chapman-Carreira protocol5 (Scheme 4.2f). The (3-hydroxy ketone 21, obtained by a diastereoselective boron aldol reaction between 19 and 20, was reduced with tetramethylammonium triacetoxyborohydride to afford the anti-diol derivative 22 in greater than 19 ldiastereoselectivity. 

In a related manner, -keto imide 25 also functions as a versatile dipropionate reagent with three different stereoselective aldol reactions being reported by the Evans group (Scheme 9-9). Both syn aldol isomers, 26 and 27, are available from either the titanium or tin(II) enolates [14] and the anti adduct 28 can be accessed using the dicyclohexyl boron enolate [15], While a chiral auxiliary is present, it is the ketone a-stereocenter that controls the r-facial selectivity in these aldol reactions. 

In the Evans synthesis of the polypropionate region (Scheme 9-45), the boron-mediated anti aldol reaction of -ketoimide ent-25 with a-chiral aldehyde 145 afforded 146 with 97% ds in what is expected to be a matched addition. Adduct 146 was then converted into aldehyde 147 in readiness for union with the C -Cs ketone. This coupling was achieved using the titanium-mediated syn aldol reaction of enolate 148 leading to the formation of 149 with 97% ds. 

The utility of BF3-OEt2, a monodentate Lewis acid, for acyclic stereocontrol in the Mukaiyama aldol reaction has been demonstrated by Evans et al. (Scheme 10.3) [27, 28]. The BF3-OEt2-mediated reaction of silyl enol ethers (SEE, ketone silyl enolates) with a-unsubstituted, /falkoxy aldehydes affords good 1,3-anti induction in the absence of internal aldehyde chelation. The 1,3-asymmetric induction can be reasonably explained by consideration of energetically favorable conformation 5 minimizing internal electrostatic and steric repulsion between the aldehyde carbonyl moiety and the /i-substituents. In the reaction with anti-substituted a-methyl-/ -alkoxy aldehydes, the additional stereocontrol (Felkin control) imparted by the a-substituent achieves uniformly high levels of 1,3-anti-diastereofacial selectivity. 

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