Cinchona alkaloid, polymer-supported

Polymer-supported [e.g. 8, 9] and silica-supported [10] cinchona alkaloids have been used in the asymmetric dihydroxylation of alkenes using osmium tetroxide. Enantiomeric excesses >90% have been achieved for diols derived from styrene derivatives. 

Asymmetric induction of the Michael addition of thiols to electron-deficient alkenes (4.6.1) has been achieved in high overall conversion using both free [e.g. 12-20] and polymer-supported [e.g. 21, 22] cinchona alkaloids and their salts [23-25], but with varying degrees of optical purity. The corresponding asymmetric Michael addition of selenophenols to cyclohex-2-enones is promoted by cinchoni-dine to give a chiral product (43% ee) [26],... 

Other functionalized supports that are able to serve in the asymmetric dihydroxylation of alkenes were reported by the groups of Sharpless (catalyst 25) [88], Sal-vadori (catalyst 26) [89-91] and Cmdden (catalyst 27) (Scheme 4.13) [92]. Commonly, the oxidations were carried out using K3Fe(CN)g as secondary oxidant in acetone/water or tert-butyl alcohol/water as solvents. For reasons of comparison, the dihydroxylation of trons-stilbene is depicted in Scheme 4.13. The polymeric catalysts could be reused but had to be regenerated after each experiment by treatment with small amounts of osmium tetroxide. A systematic study on the role of the polymeric support and the influence of the alkoxy or aryloxy group in the C-9 position of the immobilized cinchona alkaloids was conducted by Salvadori and coworkers [89-91]. Co-polymerization of a dihydroquinidine phthalazine derivative with hydroxyethylmethacrylate and ethylene glycol dimethacrylate afforded a functionalized polymer (26) with better swelling properties in polar solvents and hence improved performance in the dihydroxylation process [90]. 

Nandanan, E. Sudalai, A. Ravindranathan, T. New Polymer Supported Cinchona Alkaloids for Heterogeneous Catalytic Asymmetric Dihydroxyla-tion of Olefins, Tetrahedron Lett. 1997, 38, 2577. 

Polymer-supported organocatalysts have been used for cycloaddition of ketene, 127, to chloral, 128 [141]. Use of homo-acrylate polymers of cinchona alkaloids led to formation of the desired /Mactone (S)-130 with enantioselectivity up to... 

Catalytic asymmetric alkylations of 28 have also been carried out with polymer-bound glycine substrates [43], or in the presence of polymer-supported cinchona alkaloid-derived ammonium salts as immobilized chiral phase-transfer catalysts [44], both of which feature their practical advantages especially for large-scale synthesis. 

Hodge, P., Khoshdel, E. and Waterhouse, J. Michael reactions catalyzed by polymer-supported quaternary ammonium-salts derived from cinchona and ephedra alkaloids, J. Chem. Soc., Perkin Trans. 1, 1983, 2205-2209. 

Canali, L., Song, C. E. and Sherrington, D. C. Polymer-supported bis-cinchona alkaloid ligands for asymmetric dihydroxylation of alkenes - a cautionary tale. Tetrahedron Asymmetry, 1998, 9, 1029-1034. 

To reduce the cost of the AD process immobilization of the chiral Cinchona alkaloid-derived ligands has attracted attention, too. Several approaches to address this problem have been reported [51]. The chiral ligand has been attached to solid supports comprising organic polymers or modified silica. After comple-... 

Lohray and coworkers reported the first application of silica gel-supported Cinchona alkaloids in AD in 1996 [67], A 3,6-DHQ2-pyridazine derivative was linked to a silica gel support with an attachment point at one of the quinudidine moieties (Fig. 4, catalyst 13). The alkaloidic ligand was expected to bind to the silica surface resulting in better availability of the active site compared to polymer-... 

Pioneering attempts at using cinchona alkaloids as a platform for chiral stationary phase preparation have been reported as early as in the mid-1950s by Grubhofer and Schleith [52]. The chiral anion exchange polymeric materials were prepared by immobilization of quinine (and other cinchona alkaloids) via the 9-hydroxyl group or quinuclidine nitrogen to a polymer support. However, this resulted in very low selectivities of these phases toward racemic mandelic acid as a test analyte. Results of the early studies have been reviewed in detail by Davankov [53]. 

This asymmetric dihydroxylation problem was first solved by the use of cinchona alkaloid esters (5 and 6 R = P-CIC6H4) together with a catalytic amount of osmium tetroxide [86]. The alkaloid esters act as pseudoenantiomeric ligands (Scheme 8) [87-91], They can also be supported on a polymer [92,93],... 

The asymmetric alkylation of glycine derivatives is one of the most simple methods by which to obtain optically active a-amino acids [31]. The enantioselective alkylation of glycine Schiff base 52 under phase-transfer catalysis (PTC) conditions and catalyzed by a quaternary cinchona alkaloid, as pioneered by O Donnell [32], allowed impressive degrees of enantioselection to be achieved using only a very simple procedure. Some examples of polymer-supported cinchona alkaloids are shown in Scheme 3.14. Polymer-supported chiral quaternary ammonium salts 48 have been easily prepared from crosslinked chloromethylated polystyrene (Merrifield resin) with an excess of cinchona alkaloid in refluxing toluene [33]. The use of these polymer-supported quaternary ammonium salts allowed high enantioselectivities (up to 90% ee) to be obtained. 

A few years ago Cahard reported a series of studies on the use of immobilized cinchona alkaloid derivatives in asymmetric reactions with phase-transfer catalysts [17[. Two types of polymer-supported ammonium salts of cinchona alkaloids (types A and B in Scheme 8.4) were prepared from PS, and their activity was evaluated. The enantioselectivity was found to depend heavily on the alkaloid immobilized, with the type B catalysts usually giving better results than the type A catalysts. By performing the reaction in toluene at -50 °C in the presence of an excess of solid cesium hydroxide and 0.1 mol equiv of catalyst 10, benzylation of the tert-butyl glycinate-derived benzophenone imine afforded the expected (S)-product in 67% yield with 94% ee, a value very close to that observed with the nonsupported catalyst. (Scheme 8.4, Equation b) Unfortunately-and again, inexplicably-the pseudoenantiomer of 10 proved to be much less stereoselective, affording the R)-product in only 23% ee. No mention of catalyst recycling was reported [18]. 

Scheme 8.7 Insoluble polymer-supported cinchona alkaloids.

A member of the new ligand class for the asymmetric dihydroxylation is the bis(dihydroquinidine) ether of l,4-dihydroxy-9,10-anthraquinone. Cinchona alkaloid ligands bound to soluble polymer supports" are effective catalysts for asymmetric dihydroxylation. 

Although Cinchona alkaloids are easily separated from products by acid-base extractions and recycled, immobilisation of the catalyst on polymers was investigated by Oda. In parallel with new catalyst synthesis, their immobilisation to various solid supports was also studied. Immobilised catalysts are easily isolated by filtration and reused several times, although their initial enantioselectivity is slightly lower compared with homogeneous catalysis. 

In addition, in 2(X)4 Mamoka and co-workers [72] synthesized a recyclable fluorous chiral phase-transfer catalyst which was successfully applied for the catalytic asymmetric alkylation of a glycine-imine derivative followed by extractive recovery of the chiral phase-transfer catalyst using fluorous solvent. Later, in 2010 Itsuno and co-workers [73] published a new type of polymer-supported quarternary ammonium catalysts based on either cinchona alkaloids or Maruoka s-type catalyst bound via ionic bonds to the polymeric sulfonates. 

Radical addition of thiol or thiol-modified support to the vinyl group gives the respective thioether linkage 34 and represents one of the most convenient ways to immobilize Cinchona alkaloids [163, 172]. There are also few examples of platinum-catalyzed hydrosilylation of Cinchona alkaloids toward 11-silyl-substituted derivatives 35 with the use of monomeric silanes or polysiloxane polymers [173-175]. De Vries reported rhodium-catalyzed hydroformylation of the four main members of Cinchona alkaloids carried out on a hundred gram scale. Under optimized condition, linear aldehydes 36 were selectively obtained with the yield over 80% [176]. 

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