Evans asymmetric aldol reactions enolates

A key step in the synthesis of the spiroketal subunit is the convergent union of intermediates 8 and 9 through an Evans asymmetric aldol reaction (see Scheme 2). Coupling of aldehyde 9 with the boron enolate derived from imide 8 through an asymmetric aldol condensation is followed by transamination with an excess of aluminum amide reagent to afford intermediate 38 in an overall yield of 85 % (see Scheme 7). During the course of the asymmetric aldol condensation... 

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... 

T. Nakata et al. developed a simple and efficient synthetic approach to prepare (+)-methyl-7-benzoylpederate, a key intermediate toward the synthesis of mycalamides. The key steps were the Evans asymmetric aldol reaction, stereoselective Claisen condensation and the Takai-Nozaki olefination. The diastereoselective Claisen condensation took place between a 5-lactone and the lithium enolate of a glycolate ester. 

There are also stereochemical considerations here and Holmes used the Evans asymmetric aldol reaction (chapter 27) to make the starting material 174 R=Bn. The formation of any allyl vinyl ether reagent involves no change in the stereochemistry of the allyl alcohol - this is acetal exchange at the vinyl ether or acetal centre. The enol ether was added in masked form as a selenium compound 175 (chapter 32) as selenoxides eliminate at room temperature. The stereochemistry is developed directly from that in 177 as it transforms during the [3,3] shift. 

Scheme 5 details the asymmetric synthesis of dimethylhydrazone 14. The synthesis of this fragment commences with an Evans asymmetric aldol condensation between the boron enolate derived from 21 and trans-2-pentenal (20). Syn aldol adduct 29 is obtained in diastereomerically pure form through a process which defines both the relative and absolute stereochemistry of the newly generated stereogenic centers at carbons 29 and 30 (92 % yield). After reductive removal of the chiral auxiliary, selective silylation of the primary alcohol furnishes 30 in 71 % overall yield. The method employed to achieve the reduction of the C-28 carbonyl is interesting and worthy of comment. The reaction between tri-n-butylbor-... 

In the total synthesis of (+)-trienomycins A and F, Smith et al. used an Evans aldol reaction technology to construct a 1,3-diol functional group8 (Scheme 2.1i). Asymmetric aldol reaction of the boron enolate of 14 with methacrolein afforded exclusively the desired xyn-diastereomer (17) in high yield. Silylation, hydrolysis using the lithium hydroperoxide protocol, preparation of Weinreb amide mediated by carbonyldiimidazole (CDI), and DIBAL-H reduction cleanly gave the aldehyde 18. Allylboration via the Brown protocol9 (see Chapter 3) then yielded a 12.5 1 mixture of diastereomers, which was purified to provide the alcohol desired (19) in 88% yield. Desilylation and acetonide formation furnished the diene 20, which contained a C9-C14 subunit of the TBS ether of (+)-trienomycinol. 

SL2667>. Asymmetric aldol reactions with, V-phenylselanylacetylthiazolidin-2-thione 134 have also been conducted <07S719>. Addition of various aldehydes to the enolate solution of 134 leads to aldol products 135 with excellent selectivity (dr > 96/4) for the Evans syn isomer. 

Evans synthesis of bryostatin 2 (113) also relied upon asymmetric aldol reactions for the introduction of most of the 11 stereocenters [58], At different points, the synthesis used control from an auxiliary, a chiral Lewis acid, chiral ligands on the enolate metal and substrate control from a chiral aldehyde. Indeed, this represents the current state of the art in the aldol construction of complex polyketide natural products. 

The utility of thiazolidinethione chiral auxiliaries in asymmetric aldol reactions is amply demonstrated in a recent enantioselective synthesis of apoptolidinone. This synthesis features three thiazolidinethione propionate aldol reactions for controlling the configuration of 6 of 12 stereogenio centers <05JA13810>. For example, addition of aldehyde 146 to the enolate solution of A -propionyl thiazolidinethione 145 produces aldol product 147 with excellent selectivity (>98 2) for the Evans syn isomer. Compound 145 also undergoes diastereoselective aldol addition with bisaryl aldehyde 148 to give the Evans syn product 149, which is converted to eupomatilone-6 in 6 steps <05JOC9658>. 

Application of asymmetric alkylation with Evans auxiliaries Aldol Reactions with Evans Oxazolidinones The syn aldol reaction with boron enolates... 

We referred above to a synthesis of bryostatin that contained a reduction controlled by a 1,3-relationship. Evans synthesis34 contains a 1,3-selective aldol as well as a 1,3-controlled reduction The aldehyde 202, made by an asymmetric aldol reaction, was combined with the double silyl enol ether of methyl acetoacetate to give, as expected, the anti-aldol 203. However, the only Lewis acid that gave this good result was (<-PrO)2TiCl2 and not BF3 thus emphasising the rather empirical aspect of this type of control. Evans s own 1,3-controlled reduction gave the anti,anti-triol 204 that was incorporated into bryostatin. 

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. 

Independent work on asymmetric aldol reactions by Evans et al. led to the development of alternative chiral boron enolates that exhibit >100 1 facial selectivity. A pair of chiral N-acyl-2-oxazolidones (35)... 

Evans et al. utilized the chiral oxazolidones to prepare optically pure 3-hydroxy-a-amino acids, - important constituents of peptides and 3-lactams. As shown in Scheme 31, an asymmetric aldol reaction using the boron enolate derived from the V-(a-haloacyl)oxazolidone (68) provides the jyn-3-hydroxy-ot-halocarbonyl derivative (69), which is converted to the ann-3-hydroxy-a-azidocarbonyl derivative (70)... 

Asymmetric aldol reactionsThe enolate of the N-propionyl derivative of 1 can undergo highly syn-selcctivc aldol reactions to provide the non-Evans syn-aldols (16, 48). 

The synthesis of the fragment C3-C13 was achieved in five steps from 169. Treatment of the tosylated stereotetrad 169 with 5 equivalents of lithium acetylide in DMSO led an acetylenic compound which was treated with ra-Buli and methyl iodide, and then reduced by Na/NH3 to produce the E-geometry of the C12-C13 double bond with concomitant removal of the PMB group at C5, giving the primary alcohol 170 (49% yield for the three-step sequence). Swern oxidation of 170 gave the corresponding aldehyde which was involved in an Evans-type asymmetric aldol reaction with the boron enolate A to produce the adduct 171 (dr > 95/5, 90% yield). (Scheme 33). 

An aldol reaction is the addition of an enolate to an electrophile, where the electrophile is an aldehyde or a ketone. You have already seen earlier in this chapter how enolates can be used to make new C-C bonds enantioselectively when we explained how to control enolate alkylation with Evans chiral auxiliaries. Evans auxiliaries also provide one of the most straightforward ways of carrying out asymmetric aldol reactions, and we will start with an example before explaining how asymmetric aldol reactions can be done using catalytic methods. 

The diastereofacial selectivity of an asymmetric aldol reaction can also be controlled on the enolate side, and this is the basis of the second-generation methods of Evanst l and Masamune.l24] The complementary Evans auxiliaries (66) and (67) are synthesised from (5)-valine and (15,2/ )-norephedrine respectively. TheZ-enolate (68) is formed exclusively on reaction with dibutylboron triflate, and this reacts with aldehydes to give essentially only one aldol product (69). The diastereofacial selectivity derives from the bulky groups on the auxiliaries which force attack from the opposite face. 

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. 

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