Aldol polymer-supported catalysts

Rare earth metal triflates are recognized as a very efficient Lewis acid catalysts of several reactions including the aldol reaction, the Michael reaction, allylation, the Diels-Alder reaction, the Friedel-Crafts reaction, and glycosylation [110]. A polymer-sup-ported scandium catalyst has been developed and used for quinoline library synthesis (Sch. 8) [111], because lanthanide triflates were known to be effective in the synthesis of quinolines from A-arylimines [112,113]. This catalyst (103) was readily prepared from poly(acrylonitrile) 100 by chemical modification. A variety of combinations of aldehydes, amines, and olefins are possible in this reaction. Use of the polymer-supported catalyst has several advantages in quinoline library construction. 

This aldol condensation is assumed to proceed via nucleophilic addition of a ruthenium enolate intermediate to the corresponding carbonyl compound, followed by protonation of the resultant alkoxide with the G-H acidic starting nitrile, hence regenerating the catalyst and releasing the aldol adduct, which can easily dehydrate to afford the desired a,/3-unsaturated nitriles 157 in almost quantitative yields. Another example of this reaction type was reported by Lin and co-workers,352 whereas an application to solid-phase synthesis with polymer-supported nitriles has been published only recently.353... 

Silyl enol ethers are versatile reagents in organic synthesis [83]. They are used as isol-able enolate equivalents and many useful reactions have been developed using silyl enol ethers [83]. As a new approach to exploit an efficient method for combinatorial synthesis [84], silyl enol ethers were successfully immobilized on to a polymer. Polymer-supported silyl enol ethers (PSSEEs) were prepared according to Sch. 10 [85]. In aldol reactions of PSSEEs with aldehydes, it was again found that Sc(OTf)3 was an efficient catalyst [86]. An example of the preparation of a 1,3-diol library by use of PSSEEs is shown in Sch. 11. In all cases, the reactions proceeded smoothly to afford the corresponding 1,3-diols in good yields. 1,3-Diols are successfully cleaved from the... 

Aldol-type reactions of PSSEEs with acetals have been successfully performed using Sc(OTf)3 as a catalyst (Eq. 24) [88]. The reactions were performed at room temperature and the adducts were cleaved from the polymer supports by use of LiBH4 to give 1,3-dioI monoethers. The SR-MAS NMR technique was also us JKhh effect in the development the reactions. l. NaOMe/MeOH-THF n i... 

Catalyzed enantioselective Mukaiyama-aldol reactions have been developed extensively [101] and chiral polymer-supported Lewis acids are the catalysts of choice. Polymer-supported chiral A(-sulfonyloxazaborohdinones 86 and 87, prepared by copolymerization of styrene, divinylbenzene, and chiral monomers derived from L-valine and L-glutamic acid, respectively, have been used for aldol reactions [102]. The rates of reaction using the polymeric catalysts were slow and enantioselectivity was lower than was obtained by use of the low-molecular-weight counterpart (88). The best ee obtained by use of the polymeric catalyst was 90 % ee with 28 % isolated yield in the asymmetric aldol reaction of benzaldehyde with 89 (Eq. 27). 

One of the most powerful catalysts of the Mukaiyama aldol reaction is a chiral Ti(IV)-Schiff base complex 91 prepared from Ti(0 Pr)4 and enantiomerically pure salicylaldimine reported by Carreira [103-105]. This catalyst furnished aldol adducts in good yields and with excellent enantioselectivity. The Ti(IV)-Schiff base catalyst system is unique among the aldol catalysts yet reported in terms of operational simplicity, catalyst efficiency, chirality transfer, and substrate generality. Because the Ti(IV)-Schiff base complexes are remarkably efficient catalysts for the addition of ketene acetals to a wide variety of aldehydes, the polymeric version of catalyst 92 was prepared [106]. The activity and enantioselectivity of the polymer-supported chiral Ti(IV)-Schiff base complex were, however, much lower than were obtained from the low-molecular-weight catalyst (Eq. 28). 

Optically active l,l -binaphthols are among the most important chiral ligands of a variety of metal species. Binaphthol-aluminum complexes have been used as chiral Lewis acid catalysts. The l,T-binaphthyl-based chiral ligands owe their success in a variety of asymmetric reactions to the chiral cavity they create around the metal center [107,108]. In contrast with the wide use of these binaphthyls, the polymer-supported variety has been less popular. The optically active and sterically regular poly(l,l -bi-naphthyls) 96 have been prepared by nickel-catalyzed dehalogenating polycondensation of dibromide monomer 95 (Sch. 7) [109] and used to prepare the polybinaphthyl aluminum(III) catalyst 97 this had much greater catalytic activity than the corresponding monomeric catalyst when used in the Mukaiyama aldol reaction (Eq. 29). Unfortunately no enantioselectivity was observed in the aldol reaction. 

A novel type of polymer-supported Lewis acid, a microencapsulated Lewis acid catalyst was investigated by Kobayashi [117]. Sc(OTf)3 was immobilized on to polystyrene by microencapsulation—Sc(OTf)3 is physically enveloped by polystyrene and stabilized by the interaction between the jr-electrons of benzene rings and vacant orbitals of the Lewis acid. This microencapsulated catalyst was used successfully in several Lewis acid-catalyzed carbon-carbon bond-forming reactions (imino aldol, aza Diels-... 

In recent years, catalytic asymmetric Mukaiyama aldol reactions have emerged as one of the most important C—C bond-forming reactions [35]. Among the various types of chiral Lewis acid catalysts used for the Mukaiyama aldol reactions, chirally modified boron derived from N-sulfonyl-fS)-tryptophan was effective for the reaction between aldehyde and silyl enol ether [36, 37]. By using polymer-supported N-sulfonyl-fS)-tryptophan synthesized by polymerization of the chiral monomer, the polymeric version of Yamamoto s oxazaborohdinone catalyst was prepared by treatment with 3,5-bis(trifluoromethyl)phenyl boron dichloride ]38]. The polymeric chiral Lewis acid catalyst 55 worked well in the asymmetric aldol reaction of benzaldehyde with silyl enol ether derived from acetophenone to give [i-hydroxyketone with up to 95% ee, as shown in Scheme 3.16. In addition to the Mukaiyama aldol reaction, a Mannich-type reaction and an allylation reaction of imine 58 were also asymmetrically catalyzed by the same polymeric catalyst ]38]. 

Poly(ethylene glycol) grafted on crosslinked polystyrene (PEG-PS) resin has often been used as a polymer support for chiral catalysts of reactions performed in aqueous media. Peptides immobilized to PEG-PS resin have been developed and used as a catalyst for direct asymmetric aldol reactions in aqueous media (Scheme 3.19) [42]. When tripeptide-supported PEG-PS 67 was used as chiral catalyst in the reaction between 70 and acetone, the corresponding aldol product 69 was obtained with 73% ee. Kudo further developed the one-pot sequential reaction of acidic deacetalization and enanhoselective aldol reaction by using an Amberhte and PEG-ST-supported peptide catalyst 67 [43]. The enantioenriched aldol product 72 was obtained in 74% isolated yield from acetal 70 in a one-pot reaction (Scheme 3.20). 

Wennemers found that tripeptide H-Pro-Pro-Asp-NH2 was a highly active and selective catalyst for asymmetric aldol reactions [44]. This peptide was immobihzed to a polymer support and used as a catalyst for the aldol reaction of p-nitrobenzal-dehyde 73 and acetone (Scheme 3.21). By using a TentaGel-supported peptide 73 the aldol adduct 69 was obtained in 89% yield with 75% ee, while a polyethylene glycol-polyacrylamide (PEGA)-supported peptide gave the same adduct in 93% yield and 79% ee [45]. 

Very recently, Portnoy et al. described the design and synthesis of insoluble polymer-supported dendrimers bearing proline end groups for asymmetric aldol reachons [123]. The zeroth- to third-generahon supported dendrimer catalysts were prepared by ahaching (2S,4R)-4-hydroxyproline onto the insoluble PS-bound... 

The polymer-supported Zr catalyst (12) is useful for asymmetric aza-Diels-Alder cycloaddition of benzaldehyde imine to Danishefsky diene [9]. The 6-substituted BINOL-Zr(IV) catalyst is useful for the enantioselective anft -preferred aldol reaction of benzaldehyde with ketene silyl thioacetal (15) (Scheme 5.5) [ 10]. The calculated charge densities on the oxygen atoms of the BINOL derivatives revealed that there is a good correlation between the charge density and the reactivity of 6-substituted BINOL [ 10]. 

Of the inorganic supports, best results were reported for a mesoporous MCM-41 [337]. Support on ionic-liquid phases has been studied by different groups with variable results [338, 339], Of the non-conventional organic polymers, non-covalent immobilization on poly(diallyldimethylammonium) is notable [340], Catalysts 133 (15 mol.%) promoted the aldol reaction of acetone and benzaldehydes to afford the corresponding (i-hydroxyketones in 50-98% yields and 62-72% ee, which are clearly lower than those reported for other polymer-supported systems. Recycling of the catalysts was possible at least six times without loss of efficiency. More recently, proline has been attached to one DNA strand while an aldehyde was tethered to a complementary DNA sequence and made to react with a non-tethered ketone [341], To date, the work has focused more on conceptual development than on the analysis of its practical applications in organic synthesis. 

Some selected examples of hyperbranched polymer-supported catalysis are summarised in Table 4. Dendritic carbosilane structures are well suited for catalysis because they are relatively inert to common organometaUic reagents and their structures can be easily modified. For example, Frey and van Koten reported on the synthesis of a hyperbranched carbosilane, its fmctionaUsation with NCN moieties and the introduction of paUadium(II) sites into the structure [ 82 ]. This catalyst was introduced in aldol reactions and showed similar activity as the low molecular analogue. 

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. 

Polymer-supported organocatalysts are valuable materials for conducting catalytic asymmetric transformations under simple and environmentally begnin conditions [275]. A novel polymer-supported diphenylprolinol trimethylsilyl ether was synthesized by Hansen et oi. [276], and further applied as catalyst to induce a diastereo- and enantioselective three-component domino Michael/Michael/aldol... 

The use of polymer-supported bismuth catalysts for organic synthesis is highly attractive since this approach combines the advantages of the relative nontoxicity of bismuth salts with their easy separation and recyclability after reaction [131]. For example, microencapsulated Bi(0Tf)3 xH20 in polystyrene has been successfully reported for the methoxymethylation of alcohols, allylation of aldehydes, Michael-type and aldol reactions as well as Baeyer-Villiger oxidations [132]. 

While several resin- or polymer-supported Sc(OTf)3 catalysts have been developed and some of them are commercially available, a drawback of these catalysts is that their catalytic ability and reusability are still not satisfactory. Conceptually new methods, polymer incarcerated (PI) method and polymer-micelle incarcerated (PMI) have been developed to immobilize Sc(OTf)3 [100]. PMI Sc(OTf)3 is highly effective in several fundamental carbon-carbon bond-forming reactions, including Mukaiyama aldol, Mannich-type and Michael reactions. It is noted that the high catalytic activity in terms of TON (>7500) has been attained in Michael reaction. The catalyst was recovered quantitatively by simple filtration and reused several times without loss of catalytic activity, and no Sc leaching was observed in all the reactions (<0.1 ppm). 

Portnoy and coworkers immobilized chiral hydroxyproline derivatives on polystyrene support functionalized with polyether dendrons (Scheme 15.45).These catalysts promoted the aldol addition of acetone to aromatic aldehydes with excellent enantioselec-tivities, significantly superior to those achieved in the same reaction with analogous catalyst lacking the dendritic interface. The same group prepared polymer-supported chiral bifunctional aminocarbamate and aminourea catalysts for nitro-Michael reaction (Scheme 15.46). However, in this case the dendritic catalysts were inferior to their simpler dendron-lacking analogues. 

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