Silyl ketene acetals, aldolization reactivity

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. 

BLA 28 is very useful in the double stereodifferentiation of aldol-type reactions of chiral imines [41], Reaction of (5)-benzylidene-a-methylbenzylamine with trimethyl-silyl ketene acetal derived from tert-butyl acetate in the presence of (R)-28 at -78 °C for 12 h provides the corresponding aldol-type adduct in 94 % de (Eq. 78). Including phenol in the reaction mixture does not influence the reactivity or the diastereoselec-tivity. The aldol-type reaction using yellow crystals of (R)-28.(5)-benzylidene-a-methylbenzylamine PhOH proceeds with unprecedented (> 99.5 0.5) diastereoselec-tivity (Eq. 79). In general, 28 is a more efficient chiral Lewis acid promoter than 27. 

Myers has studied the remarkable chemistry of cyclic silyl ketene acetals 14 prepared from optically active (5)-prolinol propionamides and dichlorodimethylsi-lane (Eq. (8.5)) [7]. The reactive species is generated upon deprotonation of the prolinol amide and treatment with the silyl dichloride. The enoxysilane may be purified by distillation under reduced pressure and utilized in aldol additions to afford on/i-adducts 15 in >99% diastereomeric purity. 

Enoxysilacyclobutanes. These compounds can be prepared by Wurtz coupling of 3-chloropropyltrichlorosiIane with Mg in ether. Introduction of one alkyl group is accomplished by reaction with an organolithium reagent, and the silyl chloride can then be used for the formation of silyl enol ethers. Such 0-silyl ketene acetals are extremely reactive in aldol condensations with aldehydes without catalysts. The reaction is syn-selective. An asymmetric version uses silyl ketene acetals bearing a chiral Si-alkoxy (e.g., 8-phenylmenthoxy) group instead of an alkyl substituent. 

Following from the examples of allyltrichlorosilanes 21.5, Denmark introduced the related eno)g4 richlorosilanes 21.97 (Scheme 21.13) to cany out Mukaiyama-lype nucleophilic additions to carbonyl compounds. " According to Mayr s nucleophilicity scale, silyl enol ethers derived from aldehydes and ketones and, in particular, silyl ketene acetals are even more powerful nucleophilic reagents than the respective allyl silanes. Indeed, the aldol-type addition of trichlorosilyl enol ethers 21.97a-d to aldehydes 21.4 proceeds readily at room temperature without a catalyst exhibiting simple first-order kinetics in each component (Scheme 21.13), which contrasts with the lack of reactivity of allyl silanes in the absence of a catalyst. 

The range of substrates in the aldol reaction (and in allylation, see Section 21.2) employing trichlorosilyl reagents is generally restricted to aldehydes, while less-reactive ketones remain essentially inert. However, the exceptionally high nucleophilicity of silyl ketene acetals provides an opportunity to employ ketones as substrates (Scheme 21.14). In the absence of an activator, addition of trichlorosilyl ketene acetal 21.109 to acetophenone (21.108, = Ph, = Me, Scheme 21.14) slowly takes place at 0 °C, paving... 

At the time the chemistry of main group enolates flourished already for a while, that of late transition metals had a shadowy existence in synthetic organic chemistry. Their stoichiometric preparation and the sluggish reactivity - tungsten enolates, for example, required irradiation to undergo an aldol addition [24a] - did not seem to predestine them to become versatile tools in asymmetric syntheses [27]. The breakthrough however came when palladium and rhodium enolates were discovered as key intermediates in enantioselective catalyses. After aldol reactions of silyl enol ethers or silyl ketene acetals under rhodium catalysis were shown to occur via enolates of the transition metal [8] and after the first steps toward enantioselective variants were attempted [28], palladium catalysis enabled indeed aldol additions with substantial enantioselectivity... 

In 2009, List introduced a binaphthyl-derived, chiral disuUbnimide (28) as a new structural motif of a powerful chiral Bronsted add that could activate simple aldehydes [80, 81]. Evaluation of the catalytic activity and stereocontrolling ability of 28 in the Mukaiyama aldol reaction of silyl ketene acetal with naphthaldehyde revealed that 28 was not only far more reactive than phosphoric acid 29 and phos-phoramide 30 but also capable of affording the aldol product with high enantiose-lectivity (Scheme 7.53). 

AldolCondensations. Cation-exchanged montmorillonites accelerate the aldol condensation of silyl enol ethers with acetals and aldehydes. Similarly, the aldol reaction of silyl ketene acetals with electrophiles is catalyzed by solid-acid catalysts. Neither report discussed the use of iron montmorillonite for these reactions however, some reactivity is anticipated. 

Montmorillonite K10 was also used for aldol the reaction in water.280 Hydrates of aldehydes such as glyoxylic acid can be used directly. Thermal treatment of K10 increased the catalytic activity. The catalytic activity is attributed to the structural features of K10 and its inherent Bronsted acidity. The aldol reactions of more reactive ketene silyl acetals with reactive aldehydes proceed smoothly in water to afford the corresponding aldol products in good yields (Eq. 8.104).281... 

The proposed catalytic cycle of Evans enantioselective Cu(II)-catalyzed aldol addition is shown in Scheme 5.68. First, benzyloxyacetaldehyde 219a forms a chelate complex 226 with the metal, thus activating the carbonyl compound to become sufficiently reactive. The nucleophilic addition of silyl 0,S-ketene acetal 220 to this complex leads to the copper aldolate 227. Silylation yields the intermediate 228, whose decomplexation results in the formation of the silyl-protected aldol adduct and liberates the PYBOX catalyst 217. Crossover experiments revealed that the silyl transfer is a clear intermolecular process. 

The uncatalyzed aldol reaction of highly reactive enoxysilanes such as enoxysilacyclobutanes has previoudy been reported to proceed through six-membeied cyclic transition states (32,55), and the torsional structure of the difluoroketene acetal 5 is considered to be more suitable for the uncatalyzed aldol reaction tfian the planar geometry of 4 because the acetal 5 has a geometrical similarity to the ketene acetal in die cyclic transition states. As mentioned above (Scheme 1), a 60 40 mixture of the syn- and anri-aldols was obtained at 40°C from the bromofluoroketene silyl acetal 2 (E/Z =62/38), suggesting that the uncatalyzed aldol reaction of the fluorine-substituted ketene acetals 1 and 2 proceeds preferentially through boat-like cyclic transition states. Denmark et aL proposed diat the boat-like transition states are extremely predominant in the uncatalyzed aldol reaction of enoxysilacyclobutanes and trichlorosilyl enolates (55,54). 

In aldol reactions, especially Mukaiyama aldol reactions, TiIV compounds are widely employed as efficient promoters. The reactions of aldehydes or ketones with reactive enolates, such as silyl enol ethers derived from ketones, proceed smoothly to afford /3-hydroxycarbonyl compounds in the presence of a stoichiometric amount of TiCl4 (Scheme 17).6, 66 Many examples have been reported in addition to silyl enol ethers derived from ketones, ketene silyl acetals derived from ester derivatives and vinyl ethers can also serve as enolate components.67-69... 

The authors apphed this new concept to chemoselective functionalization of carbonyls rather than acetals [194], which is usually quite difficult to achieve because of the high reactivity of the acetal counterparts with Lewis acids. Reaction of a mixture of 1 equiv. each of acetophenone and its dimethyl acetal with ketene silyl acetal 191 under the influence of bidentate aluminum Lewis acid 188 in CH2CI2 at -78 °C for 3 h afforded aldol products 195 exclusively (88 % yield). It is worth noting that employment of dibutyltin bis(triflate) (DBTT) (10 mol%) as catalyst [195], which is quite useful for activation of aldehyde carbonyls rather than acetals, gave unsatisfactory results, producing the y3-methoxy ester preferentially (Sch. 147). 

Several examples of Sc(OTf)3-catalyzed aldol reactions of silyl enolates with aldehydes were been examined. Silyl enolates derived from ketones, thioesters, and esters reacted smoothly with different types of aldehyde in the presence of 5 mol % Sc(OTf)3 to afford the aldol adducts in high yields. Sc(OTf)3 was also found to be an effective catalyst in aldol-type reactions of silyl enolates with acetals. The reactions proceeded smoothly at -78 °C or room temperature to give the corresponding aldol-typc adducts in high )delds without side-reaction products. It should be noted that aldehydes were more reactive than acetals. For example, while 3-phenylpropionalde-hyde reacted with the ketene silyl acetal of methyl isobutyrate at -78 °C to give the aldol adduct in 80 % yield, no aldol-type adduct was obtained at -78 °C in the reaction of the same ketene silyl acetal with 3-phenylpropionaldehyde dimethyl acetal. The acetal reacted with the ketene silyl acetal at 0 °C to room temperature to give the... 

If rhodium enolates are used in a catalytic cycle they can promote aldol reactions under reasonably mild conditions. For example, the aldol reactions of trimethylsilyl enol ethers and ketene silyl acetals (37) with aldehydes can be catalyzed by various rhodium(I) complexes, under essentially neutral conditions, to give p-trimethylsiloxy ketones and esters (38 equation 14 and Table 6). The study of Matsuda and coworkers suggests that use of the rhodium complex Rlu(CO)i2 (39 at 2 mol %) in benzene at 100 C gives best results for the formation of adduct (38 Table 6, entries 1-7). There is negligible diastereoselectivity in most cases. Various cationic ihodium complexes such as (40) also catalyze the reaction. Reetz and Vougioukas have found that this aldol reaction proceeds well with the more reactive ketene silyl acetals, (37) for R = OMe or OEt, in CH2CI2 at room temperature (Table 6, entries 8-13). The intermediacy of an ti -O-bound rhodium enolate, such as (41), in the catalytic cycle is like-... 

Although the development of a range of catalytic asymmetric aldol-type reactions has proven to be a valuable contribution to asymmetric synthesis [35—37], in all of these reactions pre-conversion of the ketone moiety to a more reactive species such as an enol silyl ether, enol methyl ether, or ketene silyl acetal has been an unavoidable necessity. However, quite recently Shibasaki et al. reported that a direct catalytic asymmetric aldol reaction, which is known in enzyme chemistry, is also possible in the presence of heterobimetallic lanthanoid catalysts [38]. Using fR)-LLB (20 mol%), which shows both Lewis acidity and Bron-sted basicity similar to the corresponding aldolases, the desired optically active aldol adducts were obtained with up to 94% ee. A variety of aldehydes and unmodified ketones can be used as starting materials (Scheme 11). 

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