Silyl ketene acetals formation

If HMPA is included in the solvent, the Z-enolate predominates.236,238 DMPU also favors the Z-enolate. The switch to the Z-enolate with HMPA or DMPU is attributed to a looser, perhaps acyclic TS being favored as the result of strong solvation of the lithium ion. The steric factors favoring the -TS are therefore diminished.239 These general principles of solvent control of enolate stereochemistry are applicable to other systems.240 For example, by changing the conditions for silyl ketene acetal formation, the diastereomeric compounds 17a and 17b can be converted to the same product with high diastereoselectivity.241... 

This technology has been apphed as part of the total synthesis of myx-alamide A (Scheme 56) [139]. The stereoselective aldol reaction between aldehyde 218 and the propionate 219 dehvered, after reduction, protection, and acylation, ester 220 as a single isomer. After -silyl ketene acetal formation a [3,3]-sigmatropic rearrangement accompanied by 1,3-chirality transfer took place. This, together with the uniform prochirality at the double bonds of the... 

Marshall, J. A. Stereochemical control in the ester enolate Claisen rearrangement. Stereoselectivity in silyl ketene acetal formation. Chemtracts Org. Chem. 1991,4,154-157. 

The Ireland contribution to nonactic acid synthesis, outlined in Scheme 4.32, involves a selective silyl ketene acetal formation and Claisen rearrangement in the key step. D-Mannose (209) was readily converted in a straightforward manner to dihydrofuran 212 via 210 and 211 in 36% overall yield. Esterification of the free alcohol with propionyl chloride followed by the an enolate Claisen rearrangement afforded a mixture (89 11) of tetrahydrofuryl propionates 213 after catalytic reduction. 

Table 3 Effects of reaction condition on (Z) E) ratio of TBDMS silyl ketene acetal formation of ethyl propionate...

Table 3 Effects of Reaction Conditions on (Z) ( ) Ratio of TBDMS Silyl Ketene Acetal Formation of Ethyl Propionate...

Alternative catalytic asymmetric acylation reactions studied prochiral silyl imi-noketenes 89 [110] (Fig. 44, top) and silyl ketene acetals 90 [111, 112] (Fig. 44, middle), leading to the formation of quaternary stereocenters. Furthermore, the... 

The enolates of other carbonyl compounds can be used in mixed aldol reactions. Extensive use has been made of the enolates of esters, thiol esters, amides, and imides, including several that serve as chiral auxiliaries. The methods for formation of these enolates are similar to those for ketones. Lithium, boron, titanium, and tin derivatives have all been widely used. The silyl ethers of ester enolates, which are called silyl ketene acetals, show reactivity that is analogous to silyl enol ethers and are covalent equivalents of ester enolates. The silyl thioketene acetal derivatives of thiol esters are also useful. The reactions of these enolate equivalents are discussed in Section 2.1.4. 

The stereochemistry of the silyl ketene acetal can be controlled by the conditions of preparation. The base that is usually used for enolate formation is lithium diisopropyl-amide (LDA). If the enolate is prepared in pure THF, the F-enolate is generated and this stereochemistry is maintained in the silyl derivative. The preferential formation of the F-enolate can be explained in terms of a cyclic TS in which the proton is abstracted from the stereoelectronically preferred orientation perpendicular to the carbonyl plane. The carboxy substituent is oriented away from the alkyl groups on the amide base. 

The silyl ketene acetal rearrangement can also be carried out by reaction of the ester with a silyl triflate and tertiary amine, without formation of the ester enolate. Optimum results are obtained with bulky silyl triflates and amines, e.g., f-butyldimethylsilyl triflate and (V-methyl-Af, /V-dicyclohcxylaminc. Under these conditions the reaction is stereoselective for the Z-silyl ketene acetal and the stereochemistry of the allylic double bond determines the syn or anti configuration of the product.243... 

Scheme 6.25. Zr-catalyzed addition of silyl ketene acetals to aldehydes requiring added iPrOH, which is proposed to facilitate silyl transfer and release of the active catalyst after each C-C bond formation.

In contrast to these transformations, Michael additions of simple enolates to acceptor-substituted dienes often yield mixtures of 1,4- and 1,6-addition products27-30. For example, a 70 30 mixture of 1,4- and 1,6-adducts was isolated from the reaction of the lithium enolate of methyl propionate with methyl sorbate30. This problem can be solved by using the corresponding silyl ketene acetal in the presence of clay montmorillonite as acidic promoter under these conditions, almost exclusive formation of the 1,4-addition product (syn/anti mixture) was observed (equation ll)30. Highly regioselective 1,4-additions... 

The undefined mechanism of the aldol-type Mukaiyama and Sakurai allylation reactions arose the discussion and interest in mechanistic studies [143-145]. The proposed mechanism was proved to proceed through the catalytic activation of the aldehyde and its interaction with the silyl ketene acetal or allylsilane producing the intermediate. From that point the investigation is complicated with two possible pathways that lead either to the release of TMS triflate salt and its electrophihc attack on the trityl group in the intermediate or to the intramolecular transfer of the TMS group to the aldolate position resulting in the evolution of the trityl catalyst and the formation of the product (Scheme 51). On this divergence, series of experimental and spectroscopic studies were conducted. 

The addition of acetate-derived, achiral lithium enolates to monoprotected a-amino aldehydes is controlled by chelation, and leads to a modest stereochemical preference in favor of the 3,4-syn configuration (Table 1, entry a). 18 The formation of the 3, A-syn-product is enhanced by the use of acetate-derived silyl ketene acetals and the addition of titanium(IV) chloride or tin(IV) chloride to the reaction mixture (Table 1, entries b and c). 22-23 The same enolates add stereoselectively to A2 A-dibenzyl a-amino aldehydes but with diastereomeric ratios in favor of the Felkin-Ahn 3,4-anti-product (Table 1, compare entries a and d, and b and f). 22-24 Reverse stereocontrol is observed in the presence of a Lewis acid such as tita-nium(IV) chloride, but the yield is low (Table 1, entry e). 24 ... 

The use of aryl-A3-iodanes for C-heteroatom bond formation at the a-carbon atoms of ketones and / -dicarbonyl compounds, and related transformations of silyl enol ethers and silyl ketene acetals, has been exhaustively summarized in recent reviews (Scheme 27) [5,8]. Reactions of this type are especially useful for the introduction of oxygen ligands (e. g., L2 = OH, OR, OCOR, 0S02R, OPO(OR)2), and have been extensively utilized for the synthesis of a-sulfonyl-oxy ketones and a-hydroxy dimethyl ketals. 

Acrylates polymerize two orders of magnitude faster than methacrylates by anion catalyzed GTP however, the polymerization dies at about 10,000 MW. During the anion catalyzed polymerization of acrylates the silyl ketene acetal end groups migrate to internal positions. These ketene acetals are too hindered to act as initiators for branch formation [9]. 

In the dissociative mechanism the exchange is readily explained by the formation and dissociation of the enolate ends with neutral silyl ketene acetal ends (Scheme 13). The lack of exchange of fluorosilane with enolate ends could be caused by the complex with fluorosilane breaking only at the SiO bond to revert to fluorosilane (no exchange). 

Silyl ketene acetals from esters.1 Ireland has examined various factors in the enolization and silylation of ethyl propionate (1) as a model system. As expected from previous work (6, 276-277), use of LDA (1 equiv.) in THF at —78 -+ 25° results mainly in (E)-2, formed from the (Z)-enolate. The stereoselectivity is markedly affected by the solvent. Addition of TMEDA results in a 60 40 ratio of (Z)- and (E)-2 and lowers the yield significantly. Use of THF/23% HMPA provides (Z)- and (E)-2 in the ratio of 85 15 with no decrease in yield. This system has been widely used for (E)-selective lithium enolate formation from esters and ketones. Highest stereoselectivity is observed by addition of DMPU, recently introduced as a noncar-... 

A number of factors other than the solvent can affect the stereoselectivity of deprotonation of esters, such as the acid-base ratio and the nature of the base. But selective formation of (E)-silyl ketene acetals from esters remains a problem, particularly since they are more reactive than the (Z)-isomers. 

Fu has also explored intermolecular C-acetylation of silyl ketene acetals by AC2O for the formation of quaternary stereocenters catalyzed by planar chiral fer-... 

Fu has demonstrated that acetate anion attack on the silicon center of the silyl ketene acetal, as well as formation of an acyl pyridinium salt, contribute towards the promotion of these reactions [62]. Additionally, silyl ketene imines have also been shown to participate in analogous asymmetric C-acylation reactions to yield chiral quaternary nitriles, and this method was employed as a key step in the synthesis of verapamil [65]. 

The major products obtained from these reactions together with a detailed discussion of the factors that influence the formation of Z- and E-silyl ketene acetals may be found in Ireland, R.E., Wipf, P. and Armstrong, J.D. (1991). /. Am. Chem. Soc., 56, 650.]... 

Fig. 13.22. O-Silylation of an ester enolate to give a silyl ketene acetal. (The formation of the silicate complex in step 1 of the reaction is plausible but has not yet been proven.)...

---