Aldehydes aldol reaction, stereoselective addition

In conclusion, chiral heterobimetallic lanthanoid compexes LnMB, which were recently developed by Shibasaki et al., are highly efficient catalysts in stereoselective synthesis. This new and innovative type of chiral catalyst contains a Lewis acid as well as a Bronsted base moiety and shows a similar mechanistic effect as observed in enzyme chemistry. A broad variety of asymmetric transformations were carried out using this catalysts, including asymmetric C-C bond formations like the nitroaldol reaction, direct aldol reaction, Michael addition and Diels-Alder reaction, as well as C-0 bond formations (epoxidation of enones). Thereupon, asymmetric C-P bond formation can also be realized as has been successfully shown in case of the asymmetric hydrophosphonylation of aldehydes and imines. It is noteworthy that all above-mentioned reactions proceed with high stereoselectivity, resulting in the formation of the desired optically active products in high to excellent optical purity. 

Michael-aldol reaction tandem. Addition of lithium benzenethiolate to conjugated esters in the presence of aldehydes is followed by an aldol reaction in a stereoselective manner. 

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. 

Tin enolates are also used in aldol reactions.27 Both the Sn(II) and Sn(IV) oxidation states are reactive. Tin(II) enolates can be generated from ketones and Sn(II)(03SCF3)2 in the presence of tertiary amines.28 The subsequent aldol addition is syn selective and independent of enolate configuration.29 This preference arises from avoidance of gauche interaction of the aldehyde group and the enolate P-substituent. The syn stereoselectivity indicates that reaction occurs through an open TS. 

Silyltitanation of 1,3-dienes with Cp2Ti(SiMe2Ph) selectively affords 4-silylated r 3-allyl-titanocenes, which can further react with carbonyl compounds, C02, or a proton source [26]. Hydrotitanation of acyclic and cyclic 1,3-dienes functionalized at C-2 with a silyloxy group has been achieved [27]. The complexes formed undergo highly stereoselective addition with aldehydes to produce, after basic work-up, anti diastereomeric (3-hydroxy enol silanes. These compounds have proved to be versatile building blocks for stereocontrolled polypropionate synthesis. Thus, the combination of allyltitanation and Mukayiama aldol or tandem aldol-Tishchenko reactions provides a short access to five- or six-carbon polypropionate stereosequences (Scheme 13.15) [28],... 

Among chiral auxiliaries, l,3-oxazolidine-2-thiones (OZTs) have attracted important interest thanks to there various applications in different synthetic transformations. These simple structures, directly related to the well-documented Evans oxazolidinones, have been explored in asymmetric Diels-Alder reactions and asymmetric alkylations (7V-enoyl derivatives), but mainly in condensation of their 7V-acyl derivatives on aldehydes. Those have shown interesting characteristics in anti-selective aldol reactions or combined asymmetric addition. Normally, the use of chiral auxiliaries which can accomplish chirality transfer with a predictable stereochemistry on new generated stereogenic centers, are indispensable in asymmetric synthesis. The use of OZTs as chiral copula has proven efficient and especially useful for a large number of stereoselective reactions. In addition, OZT heterocycles are helpful synthons that can be specifically functionalized. 

The reactions proceeded efficiently under mild conditions in short time. The silyl enol ethers reacted with the activated acetals or aldehydes at -78 °C to give predominant erythro- or threo-products [136, 137] respectively. In the same manner, the aldol reaction of thioacetals, catalyzed by an equimolar amount of catalyst, resulted in <-ketosulfides [139] with high diastereoselectivity. In the course of this investigation, the interaction of silyl enol ethers with a,]3-unsaturated ketones, promoted by the trityl perchlorate, was shown to proceed regioselec-tively through 1,2- [141] or 1,4-addition [138]. The application of the trityl salt as a Lewis acid catalyst was spread to the synthesis of ]3-aminoesters [142] from the ketene silyl acetals and imines resulting in high stereoselective outcome. 

SCHEME 21. Synthesis of N-protected a-amino acids and aldehydes by stereoselective addition of bromohthioalkene 5 -41 to sulfonyhmines. Mukaiyama aldol reaction of a-aminoaldehydes... 

After mercury(II)-assisted hydrolysis of the thioenol ether, aldehyde 3 was obtained. This was then subjected to the critical vinylogous aldol reaction needed to complete the carbon backbone of the natural product. The latter process furnished a 3.5 1 mixture of the y to ot addition products. The stereoselectivity observed in the installation of the C(5)-hydroxyl (natural product numbering) was only 2 1. Fortunately, the predominant isomer was the desired product 2. In retrospect, it can be seen that the level of selectivity attained conformed to the predictions of the Still model.4... 

First, chemoselective (Chapter 24) conjugate addition of the silyl ketene acetal on the enone is preferred to direct aldol reaction with the aldehyde. Then an aldol reaction of the intermediate silyl enol ether on the benzaldehyde follows. The stereoselectivity results, firstly, from attack of benzalde-hyde on the less hindered face of the intermediate silyl enol ether, which sets the two side chains trans on the cyclohexanone, and, secondly, from the intrinsic diastereoselectivity of the aldol reaction (this is treated in some detail in Chapter 34). This is a summary mechanism. 

Once again, ( )-carvone was chosen as starting material (Scheme 48) (727). Aldol reaction with formaldehyde led to 6-hydroxymethylcarvone. The primary alcohol was protected as silylether 415 to permit addition of (cyanomethyl)lithium. The 5 1 mixture of epimeric tertiary alcohols was separated and the main product, 416, the alcohol generated by axial attack, was protected stereoselectively as bromoether 417 utilizing pyridinium hydrobromide perbromide. To introduce the necessary alkyne, the nitrile was reduced to the aldehyde with diisobutylaluminum hydride and subsequent hydrolysis. Addition of the alkyne led to a 2 1 mixture of... 

Silver(I)-Catalyzed Aldol Reaction. In 1991 the silver(I)-catalyzed aldol reaction of an aldehyde with an a-isocyanoacetate ester was reported, analogous to the above mentioned gold(I)-catalyzed reaction. The catalyst was prepared in situ from (2) and Silver(I) Perchlorate. The stereoselectivity of the silver(I)-catalyzed reaction was shown to be temperature dependent, which was attributed to the variation of the degree of metal coordination with temperature. Slow addition of the a-isocyanoacetate ester to a mixture of the aldehyde and catalyst, which favored the preferred tricoordinate Ag, gave high diastereo- and enantioselec-tivity (eq 3). 

Aldol Reactions of Ester Derivatives. The Titanium(IV) C/tlor/dc-catalyzed addition of aldehydes to 0-silyl ketene acetals derived from acetate and propionate esters proceeds with high stereoselectivity. Formation of the silyl ketene acetal was found to be essential for high diastereoselectivity. Treatment of the silyl ketene acetal, derived from deprotonation of the acetate ester with LICA in THF and silyl trapping, with a corresponding aldehyde in the presence of TiCU (1.1 equiv) afforded the addition products in 93 7 diastereoselectivity and moderate yield (51-67%). Similarly, the propionate ester provides the anti-aldol product in high antilsyn selectivity (14 1) and facial selectivity (eq 4). 

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. 

In addition to enol silyl ethers, an optically active boryl enolate underwent the highly anri-stereoselective aldol reaction with a wide variety of aldehydes in the presence of TiCU (Eq. 34) [120]. The vinyl sulfides shown in Eq. (35) reacted with a,fi-unsaturated ketones via the 1,4-addition pathway in the presence of a titanium salt, but the reaction was followed by the cleavage of a carbon-carbon bond in the cycloalkane to give open chain products in a stereoselective manner [121]. The 1,2-type addition was observed, if the olefinie acetal was used instead of the corresponding carbonyl compound, as shown in Eq. (36) [121], The successive scission of the carbon-carbon bond took place analogously to give the same type of products as shown in Eq. (35). 

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