Aldol stereoselectivity

Ketones, in which one alkyl group R is sterically demanding, only give the trans-enolate on deprotonation with LDA at —12°C (W.A. Kleschick, 1977, see p. 60f.). Ketones also enolize regioseiectively towards the less substituted carbon, and stereoselectively to the trans-enolate, if the enolates are formed by a bulky base and trapped with dialkyl boron triflates, R2BOSO2CF3, at low temperatures (D A. Evans, 1979). Both types of trans-enolates can be applied in stereoselective aldol reactions (see p. 60f.). 

The classical aldol addition, which is usually run in protic solvents, is reversible. Most modern aldol methodologies, however, rely on highly reactive preformed metal enolates, whereby proton donors are rigorously excluded. As a consequence, the majority of recent stereoselective aldol additions are performed under kinetic control. Despite this, reversibility and, as a consequence, an equilibration of yrn-aldolates to a t/-aldolates by retro-aldol addition, should not be excluded a priori. 

In contrast, highly stereoselective aldol reactions are feasible when the boron etiolates of the mandelic acid derived ketones (/ )- and (5,)-l- t,r -butyldimethylsiloxy-l-cyclohexyl-2-butanone react with aldehydes33. When these ketones are treated with dialkylboryl triflate, there is exclusive formation of the (Z)-enolates. Subsequent addition to aldehydes leads to the formation of the iyn-adducts whose ratio is 100 1 in optimized cases. 

In another approach, a glucose-derived titanium enolate is used in order to accomplish stereoselective aldol additions. Again the chiral information lies in the metallic portion of the enolate. Thus, the lithiated /m-butyl acetate is transmetalated with chloro(cyclopentadienyl)bis(l,2 5,6-di-0-isopropylidene- -D-glucofuranos-3-0-yl)titanium (see Section I.3.4.2.2.I. and 1.3.4.2.2.2.). The titanium enolate 5 is reacted in situ with aldehydes to provide, after hydrolysis, /i-hydroxy-carboxylic acids with 90 95% ee and the chiral auxiliary reagent can be recovered76. 

Figure 10.19 Oxidative enzymatic generation of dihydroxyacetone phosphate in situ for stereoselective aldol reactions using DHAP aldolases (a), and extension by pH-controlled, integrated precursor preparation and product liberation (b).

Reagents are available nowadays for acyl anions other than (4). Thus when Heathcock made the ketone (16), which he used in stereoselective aldol reactions, he needed a-hydroxy ketone (17), This required synthon (18) for which an acetylene is not a good choice as there are as yet no means of controlling the reglo-selectivity of hydration of (19). 

The requirement that an enolate have at least one bulky substituent restricts the types of compounds that give highly stereoselective aldol additions via the lithium enolate method. Furthermore, only the enolate formed by kinetic deprotonation is directly available. Whereas ketones with one tertiary alkyl substituent give mainly the Z-enolate, less highly substituted ketones usually give mixtures of E- and Z-enolates.7 (Review the data in Scheme 1.1.) Therefore efforts aimed at increasing the stereoselectivity of aldol additions have been directed at two facets of the problem (1) better control of enolate stereochemistry, and (2) enhancement of the degree of stereoselectivity in the addition step, which is discussed in Section 2.1.2.2. 

The syntheses in Schemes 13.45 and 13.46 illustrate the use of oxazolidinone chiral auxiliaries in enantioselective synthesis. Step A in Scheme 13.45 established the configuration at the carbon that becomes C(4) in the product. This is an enolate alkylation in which the steric effect of the oxazolidinone chiral auxiliary directs the approach of the alkylating group. Step C also used the oxazolidinone structure. In this case, the enol borinate is formed and condensed with an aldehyde intermediate. This stereoselective aldol addition established the configuration at C(2) and C(3). The configuration at the final stereocenter at C(6) was established by the hydroboration in Step D. The selectivity for the desired stereoisomer was 85 15. Stereoselectivity in the same sense has been observed for a number of other 2-methylalkenes in which the remainder of the alkene constitutes a relatively bulky group.28 A TS such as 45-A can rationalize this result. 

In the synthesis in Scheme 13.46, a stereoselective aldol addition was used to establish the configuration at C(2) and C(3) in Step A. The furan ring was then subjected to an electrophilic addition and solvolytic rearrangement in Step B. 

In the presence of zinc chloride, stereoselective aldol reactions can be carried out. The aldol reaction with the lithium enolate of /-butyl malonate and various a-alkoxy aldehydes gave anti-l,2-diols in high yields, and 2-trityloxypropanal yielded the syn-l,2-diol under the same conditions.633 Stoichiometric amounts of zinc chloride contribute to the formation of aminoni-tropyridines by direct amination of nitropyridines with methoxyamine under basic conditions.634 Zinc chloride can also be used as a radical initiator.635... 

Two stereoselective aldol reactions, followed by a nitrile oxide cycloaddition and a stereoselective late-stage epoxidation are the key steps in the total synthesis of myriaporones 1, 3, and 4 (436, 437, and 438). The synthesis allows... 

Usually, (Z)-boron enolates can be prepared by treating /V-acyl oxazolidones with di-K-butylboron triflate and triethylamine in CH2CI2 at 78°C, and the enolate then prepared can easily undergo aldol reaction at this temperature to give a, vy -aldol product with more than 99% diastereoselectivity (Scheme 3-4). In this example, the boron counterion plays an important role in the stereoselective aldol reaction. Triethylamine is more effective than di-wo-propylethyl amine in the enolization step. Changing boron to lithium leads to a drop in stereoselectivity. 

Stereoselective aldol condensation. The stereoselectivity of the reaction of 1 with the ester 2 can be controlled by the choice of the metal enolate. The products are intermediates to 1-methylcarbapenems. 

STEREOSELECTIVE ALDOL REACTION OF DOUBLY DEPROTONATED (RM+)-2-HYDROXY-1,2,2-TRIPHENYLETHYL ACETATE (HYTRA) (R)-3-HYDROXY-4-METHYLPENTANOIC ACID (Pentanoic acid, 3-hydroxy-4-methyl-, (R)-)... 

The addition of doubly deprotonated HYTRA to achiral4 5 as well as to enantiomerically pure aldehydes enables one to obtain non-racemic (3-hydroxycarboxylic acids. Thus, the method provides a practical solution for the stereoselective aldoi addition of a-unsubstituted enolates, a long-standing synthetic problem.7 As opposed to some other chiral acetate reagents,7 both enantiomers of HYTRA are readily available. Furthermore, the chiral auxiliary reagent, 1,1,2-triphenyl-1,2-ethanediol, can be recovered easily. Aldol additions of HYTRA have been used in syntheses of natural products and biological active compounds, and some of those applications are given in Table I. (The chiral center, introduced by a stereoselective aldol addition with HYTRA, is marked by an asterisk.)... 

NATURAL PRODUCTS AND BIOLOGICALLY ACTIVE ANALOGUES PREPARED BY STEREOSELECTIVE ALDOL ADDITON OF DOUBLY DEPROTONATED (R)- AND (S)-HYTRA... 

In principle, stereoselective aldol condensations can be carried out under two distinct sets of conditions. Under the influence of acid catalysis, stabilized enol derivatives of defined geometry (M = SiMea,... 

The studies just cited demonstrate several important design features pertaining to the objective of achieving highly stereoselective aldol condensations with Group I-II metal enolates. 

Stereoselective Aldol Condensations of Dialkylamide Lithium Enolates... 

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