Mukaiyama aldol reaction with acetals

As discussed in Section III J, in general, catalytic asymmetric aldol reactions have been studied using enol silyl ethers, enol methyl ethers, or ketene silyl acetals as a starting material. So far several types of chiral catalysis have been reported.75-85 The chiral lanthanoid complex prepared from Ln(OTf)3 and a chiral sulfonamide ligand was effective in promoting an asymmetric Mukaiyama aldol reaction with a ketene silyl acetal.86 The preparation of the catalyst and a representative reaction are shown in Figure 45. 

The authors used (5)-carvotanacetone (dihydrocarvone) as starting material (Scheme 34). To prepare the linearly conjugated sUylenol ether, they used the Kharash protocol and attained y-alkylation by Mukaiyama aldol reaction with trimethylorthoformate (195). The ketoacetal 295 was a-hydroxylated according to Rubottom by silylenol ether formation followed by epoxidation and silyl migration. Acid treatment transformed 296 to the epimeric cyclic acetals 297 and 298. endo-Aceta 297 was equilibrated thereby increasing the amount of exo-acetal 298. The necessary unsaturated side chain for the prospected radical cyclization was introduced by 1,4-addition of a (trimethylsilyl)butynylcopper compound. 

Mukaiyama aldol reaction. With C cnol ethers with aldehydes can be carried oi Acetylation. Alcohols, thiols, and ar reaction with acetic anhydride at room tern are similarly transformed into gem-diaceiau N-Arylimidazoles. Together with I. as additives, Cu(OT02 and cesium carbonat... 

Paterson et al. [98] in their attempt used a similar disconnection for rhizopodin as described by Menche (fragments 144 and 149) (Scheme 2.151). However, unlike, Menche, they used silyl ketene acetal 16 in an asynunetric VMAR for the addition to ( )-iodoacrolein (142) to obtain dioxinone 143 in 94% ee. Methanolysis removed the aceto-nide, and the subsequent Narasaka reduction [99] provided the syn-diol 144 in 80% yield and a 10 1 selectivity for the desired isomer. The synthesis of segment 149 started with aldehyde 145, which was ultimately derived from Roche ester. Carbon chain extension was achieved through a chelation-controlled Mukaiyama aldol reaction with silyl ketene acetal 146, which installed the new chiral center with excellent stereocontrol (20 1 dr). For the installation of the third secondary alcohol, six-membered lactone 148 was obtained by treatment with K COj in methanol. Subsequent borane reduction provided stereospecifically the desired alcohol, which was then further transformed to the desired acid (149). 

Evans et al. applied the Mukaiyama aldol reaction to the total synthesis of the squalene synthase inhibitor zaragozic acid C (Scheme 8.23). ° Di-f-butyl tartrate 135 was protected as acetal 137, which was converted into silyl enol ether 138. The partner aldehyde 141 was synthesized by the Evans aldol reaction (139 —> 140). The Mukaiyama aldol reaction with silyl enol ether 138 and aldehyde 141 in the presence of (i-PrO)TiCl3 gave adduct 142 as a single isomer. These transformations gave the desired stereochemistry at the C3 to C7 positions. 

Masamune examined the use of Ca-alkylated a-amino acids for the generation of optically active oxazaborolidines 249 which were used as Lewis acid catalysts (Scheme 4.30) [125, 126]. The expectation in these studies was that the additional rigidity proffered by the unnatural amino acid scaffold would lead to improved selectivities. Several excellent catalysts for asymmetric Mukaiyama aldol reactions with a broad range of aldehydes were identified, both for acetate aldol reactions [125] and for the addition of isobutyrate-derived silyl enol ethers [126], as shown for the case of catalyst 249. 

Mukaiyama aldol reactions have been reported, usually using chiral additives although chiral auxiliaries have also been used. This reaction can also be run with the aldehyde or ketone in the form of its acetal R R C(OR )2> in which case the product is the ether R COCHR2CR R OR instead of 27. Enol acetates and enol ethers also give this product when treated with acetals and TiCLi or a similar catalyst. When the catalyst is dibutyltin bis(triflate), Bu2Sn(OTf)2, aldehydes react, but not their acetals, while acetals of ketones react, but not the ketones themselves. 

The Mukaiyama aldol reaction refers to Lewis acid-catalyzed aldol addition reactions of silyl enol ethers, silyl ketene acetals, and similar enolate equivalents,48 Silyl enol ethers are not sufficiently nucleophilic to react directly with aldehydes or ketones. However, Lewis acids cause reaction to occur by coordination at the carbonyl oxygen, activating the carbonyl group to nucleophilic attack. 

Several catalysts based on Ti(IV) and BINOL have shown excellent enantiose-lectivity in Mukaiyama aldol reactions.156 A catalyst prepared from a 1 1 mixture of BINOL and Ti(0-i-Pr)4 gives good results with silyl thioketene acetals in ether, but is very solvent sensitive.157... 

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... 

Pro-chiral pyridine A-oxides have also been used as substrates in asymmetric processes. Jprgensen and co-workers explored the catalytic asymmetric Mukaiyama aldol reaction between ketene silyl acetals 61 and pyridine A-oxide carboxaldehydes 62 <06CEJ3472>. The process is catalyzed by a copper(II)-bis(oxazoline) complex 63 which gave good yields and diastereoselectivities with up to 99% enantiomeric excess. 

Silyloxy)alkenes were first reported by Mukaiyama as the requisite latent enolate equivalent to react with aldehydes in the presence of Lewis acid activators. This process is now referred to as the Mukaiyama aldol reaction (Scheme 3-12). In the presence of Lewis acid, anti-aldol condensation products can be obtained in most cases via the reaction of aldehydes and silyl ketene acetals generated from propionates under kinetic control. 

The 9-catalyzed Mukaiyama-aldol reaction [74] of benzaldehyde and 1,2-dimethoxy benzaldehyde with a ketene silyl acetal in the presence of 10mol% thiourea 9 furnished the target product in low yield (36%), while the same reaction... 

Scheme 6.4 Mukaiyama-aldol reaction of benzaldehydes with a ketene silyl acetal catalyzed by thiourea 9.

One of the early syntheses of orlistat (1) by Hoffmann-La Roche utilized the Mukaiyama aldol reaction as the key convergent step. Therefore, in the presence of TiCU, aldehyde 7 was condensed with ketene silyl acetal 8 containing a chiral auxiliary to assemble ester 9 as the major diastereomer in a 3 1 ratio. After removal of the amino alcohol chiral auxiliary via hydrolysis, the a-hydroxyl acid 10 was converted to P-lactone 11 through the intermediacy of the mixed anhydride. The benzyl ether on 11 was unmasked via hydrogenation and the (5)-7V-formylleucine side-chain was installed using the Mitsunobu conditions to fashion orlistat (1). 

Aldol reactions of aldehydes with cycloakanones were performed in ionic liquids and catalyzed by FeCl3-6H20 [32]. Mukaiyama aldol reactions of silylenol ethers with aldehydes can be carried out in aqueous media however, among several Lewis acidic catalysts investigated, iron compounds were not the optimal ones [33], If silyl ketene acetals are applied as carbon nucleophiles in Mukaiyama aldol reactions, cationic Fe(II) complexes give good results. As catalysts, CpFe(CO)2Cl [34] and [CpFe(dppe) (acetone)] BF4 [35] [dppe = l,2-bis(diphenylphosphano)ethane] were applied (Scheme 8.8). No diastereomeric ratio was reported for product 26a. 

Scheme 8.8 Mukaiyama aldol reactions of silyl ketene acetals with aldehydes.

Bis(pentafluorophenyl) tin dibromide effects the Mukaiyama aldol reaction of ketene silyl acetal with ketones, but promotes no reaction with acetals under the same conditions. On the other hand, reaction of silyl enol ether derived from acetophenone leads to the opposite outcome, giving acetal aldolate exclusively. This protocol can be applied to a bifunctional substrate (Equation (105)). Keto acetal is exposed to a mixture of different types of enol silyl ethers, in which each nucleophile reacts chemoselectively to give a sole product.271... 

Aldol Addition. A catalyst generated upon treatment of Cu(OTf)2 with the (5,5)-r-Bu-box ligand has been shown to be an effective Lewis acid for the enantioselective Mukaiyama aldol reaction. The addition of substituted and unsubstituted enolsilanes at -78 °C in the presence of 5 mol % catalyst was reported to be very general for various nucleophiles, including silyl dienolates and enol silanes prepared from butyrolactone as well as acetate and propionate esters. 

Mukaiyama aldol reactions of silylketene acetal and pyruvate ester (eq 14) in the presence of 10 mol % Cu[(5,5)-/-Bu-box] (OTf)2 catalyst furnish the corresponding aldol product in excellent enantiomeric excess (98%). Furthermore, the addition reactions of ketene acetals derived from /-butyl thioacetate and ben-zyloxyacetaldehyde with only 5 mol % catalyst afford the aldol product in 91% ee (eq 15). It is also noteworthy that the addition of both propionate-derived (Z)- and ( )-silylketene acetals stereoselectively forms the jyn-adduct in 97% and 85% ee, respectively. 

The aldol reaction of ketene silyl acetals with several aldehydes (Mukaiyama aldol reaction) assisted by Li has been described briefly by Reetz et al. Wirth 5.0 m LPDE a clean reaction began within 1 h with the sole formation of the silylated aldol 112, whereas the use of a catalytic amount (3 mol %) of LiC104 in Et20 (3 mol % LPDE) required a reaction time of 5 days for 86 % conversion. As observed in the hetero-Diels-Alder reaction of a-alkoxyaldehyde, the higher rate of reaction of 79 compared with that of benzaldehyde can be attributable to chelation. Indeed, the use of 3 mol % LPDE required only 20 h at room temperature for complete uptake of 79 with a diastereoselectivity (syn-113lanti-113) of >96 % (Sch. 55). 

Mukaiyama aldol reactions of various silyl enol ethers or ketene silyl acetals with aldehydes or other electrophiles proceed smoothly in the presence of 2 mol % B(CgF5)3 [151a,c]. The following characteristic features should be noted (i) the products can be isolated as j8-trimethylsilyloxy ketones when crude adducts are worked-up without exposure to acid (ii) this reaction can be conducted in aqueous media, so that the reaction of the silyl enol ether derived from propiophenone with a commercial aqueous solution of formaldehyde does not present any problems (iii) the rate of an aldol reaction is markedly increased by use of an anhydrous solution of B(C6Fs)3 in toluene under an argon atmosphere and (iv) silyl enol ethers can be reacted with chloromethyl methyl ether or trimethylorthoformate hydroxymethyl, methoxy-methyl, or dimethoxymethyl Cl groups can be introduced at the position a to the carbonyl group. These aldol-type reactions do not proceed when triphenylborane is used (Eq. 92). 

The Mukaiyama aldol reaction of carbonyl substrates with silyl enol ethers is the most widely accepted of Lewis acid-promoted reactions. Many Lewis acids for the reaction have been developed and used enantioselectively and diastereoselectively. In 1980, catalytic amounts of la were found by Noyori et al. to effect aldol-type condensation between acetals and a variety of silyl enol ethers with high stereoselectivity [2c,20]. Unfortunately, la has poor Lewis acidity for activation of aldehydes in Mukaiyama s original aldol reaction [21]. Hanaoka et al. showed the scope and limitation of 11-cat-alyzed Mukaiyama aldol reaction, by varying the alkyl groups on the silicon atom of silyl enol ethers [22]. Several efforts have been since been made to increase the reactivity and/or the Lewis acidity of silicon. One way to enhance the catalyst activity is to use an additional Lewis acid. 

Aldol-type condensation of silyl enol ethers with acetals under the influence of la is rather familiar. Unlike the Mukaiyama aldol reaction, 1-5 mol % loading of la is enough to complete the coupling reaction under mild conditions [20]. This transformation is applicable to the synthesis of a wide variety of / -alkoxy carbonyl substrates and has three characteristic features ... 

A recent notable finding in this field is Mukaiyama aldol reactions in aqueous medium (THF H20 = 9 1) catalyzed by metal salts. Lewis acids based on Fe(II), Cu(II), and Zn(II), and those of some main group metals and lanthanides are stable in water. Remarkably, the aldol reaction shown in Sch. 29 occurs more rapidly than the hydrolysis of the silyl enol ether [137]. In the presence of surfactants (dodecyl sulfates or dodecane sulfonate salts), reactions of thioketene silyl acetals with benzaldehyde can be performed in water [138]. 

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