Aldol reaction Mukaiyama

The crossed aldol reaction of silyl enol ethers with carbonyl com- 

Scandium triflate-catalyzed aldol reactions of silyl enol ethers with aldehyde were successfully carried out in micellar systems and encapsulating systems. While the reactions proceeded sluggishly in water alone, strong enhancement of the reactivity was observed in the presence of a small amount of a surfactant. The effect of surfactant was attributed to the stabiMzation of enol silyl ether by it. Versatile carbon-carbon bondforming reactions proceeded in water without using any organic solvents. Cross-linked Sc-containing dendrimers were also found to be effective and the catalyst can be readily recycled without any appreciable loss of catalytic activity.Aldol reaction of 1-phenyl-l-(trimethylsilyloxy) ethylene and benzaldehyde was also conducted in a gel medium of fluoroalkyl end-capped 2-acrylamido-2-methylpropanesulfonic acid polymer. A nanostmctured, polymer-supported Sc(III) catalyst (NP-Sc) functions in water at ambient temperature and can be efficiently recycled. It also affords stereoselectivities different from isotropic solution and solid-state scandium catalysts in Mukaiyama aldol and Mannich-type reactions. 

Montmorillonite KIO was also used for aldol the reaction in water. Hydrates of aldehydes such as glyoxyhc acid can be used directly. Thermal treatment of KIO increased the catal c activity. The catalytic activity is attributed to the stmctural features of KIO 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).  

Polar polyoxyethylene-polyoxypropylene (POEPOP) resin, deriva-tized with a 4-hydroxymethyl phenoxy linker, was used as a solid support for lanthanide triflate-catalyzed Mukaiyama-type solid-phase aldol reactions. The use of an aqueous solvent was found to be crucial. The reactions on an N-terminal peptide aldehyde substrate proceeded in very high yields. 

2 Asymmetric Lewis-Acid Catalyzed. Another important advance in aqueous Mukaiyama aldol reaction is the recent success of asymmetric catalysis. In aqueous ethanol, Kobayashi and co-workers achieved asymmetric inductions by using Cu(OTf)2/chiral Z A(oxazoMne) Mgand, Pb(OTf)2/chiral crown ether,and Ln(OTf)3/chiral Z A-pyridino-18-crown-6 (Eq. 8.105).  

The Mukaiyama aldol reaction is the nucleophilic addition of a trimethylsilyl enol ether 1 to either an aldehyde 2 or a ketone in the presence of a Lewis acid to form a (3-hydroxyketone 3. 

Since its identification in 1872 by Charles-Adolphe Wurtz and Alexander Borodin, the aldol reaction has found immense synthetic utility in the formation of carbon-carbon bonds. The utility of the aldol reaction, however, was typically limited due to the formation of various condensation adducts. The desire to reduce the formation of unwanted byproducts led researchers to investigate modifications to the classical aldol model. One theme which emerged from studies to overcome the limitations to the aldol reaction was the incorporation of more powerful lithium amide bases for the production of kinetic and/or thermodynamic lithium enolates.  

In the following year, the Mukaiyama aldol reaction was extensively studied, covering a wide range of factors associated with the reaction. It was found that TiCU was the most effective Lewis acid due to its ability to 

Numerous in-depth mechanistic studies have been performed on the Mukaiyama aldol reaction. Although various mechanisms exist in the literature that take into account the various roles of the numerous catalysts used for the enantio- and diastereoselective Mukaiyama aldol reaction, the commonly accepted mechanism accounting for bond formation is shown below.The reaction begins with the coordination of a Lewis acid with aldehyde 4 to form complex 5. Due to its enhanced electrophilicity, complex 5 is attacked by the 7t-bond of the enol silane 6, giving rise to resonance stabilized cation 7. At this point, either intermolecular silyl cleavage upon hydrolysis or intramolecular silyl transfer to the product hydroxyl group occurs to give products such as 8 or 9. 

While the order of silyl transfer or cleavage is inconsequential to bond formation, it is one of the more important and hotly debated aspects of the mechanism owing to its importance in the development of catalytic enantioselective variants of the Mukaiyama aldol reaction. Intramolecular silyl transfer, as shown in the formation of 10, would regenerate the chiral, 

Dianions of this type react with ketones, epoxides,and esters as well as a wide variety of other electrophiles. As an example, the dilithio anion of 2-methylpropionic acid was condensed with the epoxide moiety in 229 to form an hydroxy acid, which cyclized to form the lactone ring in 230. Since most of the enolates of acid derivatives contain a leaving group, the alkoxide resulting from reaction with an epoxide often displaces that leaving group to give the lactone. 

The condensation of enolates with alkyl halides or other carbonyl derivatives allows a wide variety of synthetic and functional group transformations in the carbon-carbon bond-forming process. Enolates are, therefore, among the most powerful synthetic intermediates known. In addition to generating a new carbon-carbon bond, the reaction proceeds with high diastereoselectivity in most cases, making it even more useful. 

The acid-catalyzed aldol condensation was mentioned briefly in Section 9.4.A.i, including a reaction catalyzed by TiCU. Using traditional Brpnsted-Lowry acids generates the aldolate product, but the acidic conditions make the process reversible and poor yields can result, as well as deleterious cationic side reactions. 

For these reasons, this variation is not as widely used as the anionic reaction (the aldol condensation). The base catalyzed reaction often leads to dimers, polymers, self-condensation products or a, 5-unsaturated carbonyl derivatives, as described in Section 9.4.A. Mukaiyama and co-workers modified the acid-catalyzed reaction to include silyl enol ethers. He found that they react with carbonyl compounds to produce aldol-like 

Reaction of Silyl Enol Ethers with Benzaldehyde in the Presence of Lewis Acids 

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The use of indium in acpieous solution has been reported by Li and co-workers as a new tool in org nometallic chemistry. Recently Loh reported catalysis of the Mukaiyama-aldol reaction by indium trichloride in aqueous solution". Fie attributed the beneficial effect of water to a eg tion phenomena in connection with the high internal pressure of this solvenf This woric has been severely criticised by... 

Chiral salen chromium and cobalt complexes have been shown by Jacobsen et al. to catalyze an enantioselective cycloaddition reaction of carbonyl compounds with dienes [22]. The cycloaddition reaction of different aldehydes 1 containing aromatic, aliphatic, and conjugated substituents with Danishefsky s diene 2a catalyzed by the chiral salen-chromium(III) complexes 14a,b proceeds in up to 98% yield and with moderate to high ee (Scheme 4.14). It was found that the presence of oven-dried powdered 4 A molecular sieves led to increased yield and enantioselectivity. The lowest ee (62% ee, catalyst 14b) was obtained for hexanal and the highest (93% ee, catalyst 14a) was obtained for cyclohexyl aldehyde. The mechanism of the cycloaddition reaction was investigated in terms of a traditional cycloaddition, or formation of the cycloaddition product via a Mukaiyama aldol-reaction path. In the presence of the chiral salen-chromium(III) catalyst system NMR spectroscopy of the crude reaction mixture of the reaction of benzaldehyde with Danishefsky s diene revealed the exclusive presence of the cycloaddition-pathway product. The Mukaiyama aldol condensation product was prepared independently and subjected to the conditions of the chiral salen-chromium(III)-catalyzed reactions. No detectable cycloaddition product could be observed. These results point towards a [2-i-4]-cydoaddition mechanism. 

Eor the application of C2-symmetric bis-oxazoline-Lewis acids in other catalytic reactions (a) Mukaiyama-aldol reactions see, e.g., D.A. Evans, M.C. Kozlowski,... 

The reaction was studied in the absence, and presence, of (MeO)2AlMe as a model catalyst for the BINOL-AlMe system. The change in relative energy for the concerted hetero-Diels-Alder reaction, and formation of the hetero-Diels-Alder adduct 11 via a Mukaiyama aldol reaction, is shown in Fig. 8.13. The conclusion of the study was that in the absence of a catalyst the concerted reaction is the most... 

For example in the so-called Mukaiyama aldol reaction of an aldehyde R -CHO and a trimethylsilyl enol ether 8, which is catalyzed by Lewis acids, the required asymmetric environment in the carbon-carbon bond forming step can be created by employing an asymmetric Lewis acid L in catalytic amounts. 

Jacobsen epoxidation 359 -, Katsuki epoxidation 361 -, Mukaiyama-aldol reaction 367 f. -, oxime ether reduction 363 -, Sharpless asymmetric dihydroxyla-tion 361... 

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. 

Danshefsky s diene [19] is the 1,3-butadiene with amethoxy group at the 1-position and a trimethylsiloxy group at the 3-position (Scheme 18). This diene and Lewis acids extended the scope of hetereo-Diels-Alder reactions with aldehydes [20], This diene reacts with virtually any aldehyde in the presence of Lewis acids whereas dienes usually react with only selected aldehydes bearing strongly electron accepting a-substituents. There are two (Diels-Alder and Mukaiyama aldol) reaction pathways (Scheme 18) identified for the Lewis acids catalyzed reactions of Danishefsky diene with aldehydes [21, 22]. The two pathways suggest that these reactions occur on the boundary between the delocahzation band (the pericyclic... 

Another SBU with open metal sites is the tri-p-oxo carboxylate cluster (see Section 4.2.2 and Figure 4.2). The tri-p-oxo Fe " clusters in MIL-100 are able to catalyze Friedel-Crafts benzylation reactions [44]. The tri-p-oxo Cr " clusters of MIL-101 are active for the cyanosilylation of benzaldehyde. This reaction is a popular test reaction in the MOF Hterature as a probe for catalytic activity an example has already been given above for [Cu3(BTC)2] [15]. In fact, the very first demonstration of the catalytic potential of MOFs had aheady been given in 1994 for a two-dimensional Cd bipyridine lattice that catalyzes the cyanosilylation of aldehydes [56]. A continuation of this work in 2004 for reactions with imines showed that the hydrophobic surroundings of the framework enhance the reaction in comparison with homogeneous Cd(pyridine) complexes [57]. The activity of MIL-lOl(Cr) is much higher than that of the Cd lattices, but in subsequent reaction rans the activity decreases [58]. A MOF with two different types of open Mn sites with pores of 7 and 10 A catalyzes the cyanosilylation of aromatic aldehydes and ketones with a remarkable reactant shape selectivity. This MOF also catalyzes the more demanding Mukaiyama-aldol reaction [59]. 

Asymmetric Mukaiyama aldol reactions have also been performed in the presence of Lewis-acid lanthanoid complexes combined with a chiral sulfonamide ligand. Similar enantioselectivities of about 40% ee were obtained for all... 

Scheme 10.26 Sn-catalysed Mukaiyama aldol reaction with S/N ligands.

Scheme 10.27 Yb-catalysed Mukaiyama aldol reactions with sulfonamide ligand.

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. 

Quite a number of other Lewis acids can catalyze the Mukaiyama aldol reaction, including Bu2Sn(03SCF3)2,51 Bu3SnC104,52 Sn(03SCF3)2,53 Zn(03SCF3)2,54 and... 

In addition to aldehydes, acetals can serve as electrophiles in Mukaiyama aldol reactions.64 Effective catalysts include TiCl4,65 SnCl4,66 (CH3)3Si03SCF3,67 and... 

The Mukaiyama aldol reaction can provide access to a variety of (3-hydroxy carbonyl compounds and use of acetals as reactants can provide (3-alkoxy derivatives. The issues of stereoselectivity are the same as those in the aldol addition reaction, but the tendency toward acyclic rather than cyclic TSs reduces the influence of the E- or Z-configuration of the enolate equivalent on the stereoselectivity. 

Scheme 2.2 illustrates several examples of the Mukaiyama aldol reaction. Entries 1 to 3 are cases of addition reactions with silyl enol ethers as the nucleophile and TiCl4 as the Lewis acid. Entry 2 demonstrates steric approach control with respect to the silyl enol ether, but in this case the relative configuration of the hydroxyl group was not assigned. Entry 4 shows a fully substituted silyl enol ether. The favored product places the larger C(2) substituent syn to the hydroxy group. Entry 5 uses a silyl ketene thioacetal. This reaction proceeds through an open TS and favors the anti product. 

Control of Facial Selectivity in Aldol and Mukaiyama Aldol Reactions... 

Dipole-dipole interactions may also be important in determining the stereoselectivity of Mukaiyama aldol reactions proceeding through an open TS. A BF3-catalyzed reaction was found to be 3,5-anti selective for several (3-substituted 5-phenylpentanals. This result can be rationalized by a TS that avoids an unfavorable alignment of the C=0 and C-X dipoles.97... 

Scheme 2.6. Control of Stereochemistry of Aldol and Mukaiyama Aldol Reactions Using...

Another group of catalysts consist of cyclic borinates derived from tartaric acid. These compounds give good reactivity and enantioselectivity in Mukaiyama aldol reactions. Several structural variations such as 16 and 17 have been explored.151... 

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... 

Entries 5 to 9 illustrate some of the modified reagents and catalytic procedures. Entry 5 uses a phosphine-stabilized reagent, whereas Entry 6 includes BF3. Entry 7 involves use of TMS-C1. Entries 8 and 9 involve cyanocuprates. In Entry 9, the furan ring is closed by a Mukaiyama-aldol reaction subsequent to the conjugate addition (Section 2.1.4). 

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