Polymer-bounded catalysts resins

Soluble polymer-bound catalysts for epoxidation reactions have also been explored, with a complete study into the nature of the polymeric backbone performed by Janda [70]. Chiral (salen)-Mn complexes were appended to MeO-PEG, NCPS, Jan-daJeF and Merrifield resin via a glutarate spacer. It was found that for the Jacobsen epoxidation of ds-/ -mefhylstyrene, the enantioselectivities for each polymer-supported catalyst were comparable (86-90%) to commercially available Jacobsen catalyst (88%). Both soluble polymer-supported catalysts could be used twice before a decline in yield and enantioselectivity was observed. However, neither soluble polymer support proved as suitable as the insoluble JandaJel-supported (salen)-Mn complex for the epoxidation because residual impurities during precipitation and leaching of Mn from the complex, resulted in lowered yields. 

Polymer bound catalyst systems have become highly sophisticated. For supports, commercial resins have in cases given way to custom tailored polymers designed to optimize a supported catalyst s performance. This progression from simple to complex systems is illustrated by advances in supported catalysts used for the asymmetric hydrogenation of enamides. 

Potential recycling of the polymeric catalysts is a very important feature of supported systems. According to this, all polymer-bound catalysts prepared were recovered after the initial reaction, washed, dried and reused for the same reaction, under similar conditions. This procedure was repeated for several cycles. Results obtained showed that all resins partially lose... 

Second, Sigamide was attached to Merrifield resin A 6. The polymer bound catalyst needs higher catalyst loadings (15mol%) and shows approx. 10% lower yields and selec-tivities. On the other hand, they also showed that the catalyst can be reused five times without any loss in activity. Performing blank experiments with only the resin, it was found that the lower enantioselectivities originate from the... 

Chemistry on solid support has gained tremendous importance during the last few years, mainly driven by the needs of the pharmaceutical sciences. Due to the robust and tolerable nature of the available catalysts, metathesis was soon recognized as a useful technique in this context. Three conceptually different, RCM-based strategies are outlined in Fig. 11. In the approach delineated in Fig. 1 la, a polymer-bound diene 353 is subjected to RCM. The desired product 354 is formed with concomitant traceless release from the resin. This strategy is very favorable, since only compounds with the correct functionality will be liberated, while unwanted by-products remain attached to the polymer. However, as the catalyst is captured in this process by the matrix (355), a higher catalyst loading will be required, or ancillary alkenes have to be added to liberate the catalyst. 

Acid derivatives that can be converted to amides include thiol acids (RCOSH), thiol esters (RCOSR), ° acyloxyboranes [RCOB(OR )2]. silicic esters [(RCOO)4Si], 1,1,1-trihalo ketones (RCOCXa), a-keto nitriles, acyl azides, and non-enolizable ketones (see the Haller-Bauer reaction 12-31). A polymer-bound acyl derivative was converted to an amide using tributylvinyl tin, trifluoroacetic acid, AsPh3, and a palladium catalyst. The source of amine in this reaction was the polymer itself, which was an amide resin. 

Polymer-supported catalysts often have lower activities than the soluble catalysts because of the intraparticle diffusion resistance. In this case the immobilization of the complexes on colloidal polymers can increase the catalytic activity. Catalysts bound to polymer latexes were used in oxidation reactions, such as the Cu-catalyzed oxidation of ascorbic acid,12 the Co-catalyzed oxidation of tetralin,13 and the CoPc-catalyzed oxidation of butylphenol14 and thiols.1516 Mn(III)-porphyrin bound to colloidal anion exchange resin was... 

Several combinatorial approaches to the discovery of transition metal based catalysts for olefin polymerization have been described. In one study Brookhart-type polymer-bound Ni- and Pd-(l,2-diimine) complexes were prepared and used in ethylene polymerization (Scheme 3).60,61 A resin-bound diketone was condensed with 48 commercially available aminoarenes having different steric properties. The library was then split into 48 nickel and 48 palladium complexes by reaction with [NiBr2(dme)] and [PdClMe(COD)], respectively, all 96 pre-catalysts being spatially addressable. 

As discussed in Section 7.1.4, polymer-bound acetoacetates can be used as precursors for the solid-phase synthesis of enones [33], For these Knoevenagel condensations, the crucial step is to initiate enolization of the CH acidic component. In general, enolization can be initiated with a variety of catalysts (for example, piperidine, piperidinium acetate, ethylenediamine diacetate), but for the microwave-assisted procedure piperidinium acetate was found to be the catalyst of choice, provided that the temperature was kept below 130 °C. At higher reaction temperatures, there is significant cleavage of material from the resin. 

The actual structure of the active catalyst in the above reactions is a matter of speculation. The evidence, however, points to the presence of a homogeneous but immobilized Fischer-Tropsch catalyst. Since soluble CpCo(CO)2 does not possess Fischer-Tropsch activity, this activity is a unique feature of the polymer-bound system. The finding that 5 is regenerated quantitatively upon exposure of the active Fischer-Tropsch catalyst resin to CO implies that the n5-cyclopentadienylcobalt bond remains intact throughout the Fischer-Tropsch reaction. Similar... 

Buchwald has shown that, in combination with palladium(II) acetate or Pd2(dba)3 [tris(dibenzylideneacetone)dipalladium], the Merrifield resin-bound electron-rich dialkylphosphinobiphenyl ligand (45) (Scheme 4.29) forms the active polymer-supported catalysts for amination and Suzuki reactions [121]. Inactivated aryl iodides, bromides, or even chlorides can be employed as substrates in these reactions. The catalyst derived from ligand (45) and a palladium source can be recycled for both amination and Suzuki reactions without addition of palladium. 

Various polymer-bound (polystyrene-bound) oxazaboroHdine catalysts for the reduction of secondary alcohols were reported [128]. These can simply be prepared by condensation of the resin-bound boronic acid with chiral 1,2-amino alcohols. The best results as far as enatioselectivity is concerned were obtained with oxaza-borohdine (59) (Scheme 4.36). 

Schreiber and co-workers (436) prepared a library calculated to contain 2.18 million polycyclic compounds through the 1,3-dipolar cycloaddition of a number of nitrones with alkenes supported on TentaGel S NH2 resin (Scheme 1.83). (—)-Shikimic acid was converted into the polymer bound epoxycyclohexenol carboxylic acid 376 (or its enantiomer), coupled to the resin via a photolabile linker developed by Geysen and co-workers (437) to allow release of the products from the resin in the presence of live cells by ultraviolet (UV)-irradiation. A range of iodoaromatic nitrones (377) was then reacted with the ot,p-unsaturation of the polymer-bound amide in the presence of an organotin catalyst, using the tandem esterification/ dipolar cycloaddition methodology developed by Tamura et al. (84,85) Simultaneous cyclization by PyBrop-mediated condensation of the acid with the alcohol... 

The alternative strategy for heterogenization has been pursued by Blechert and co-workers, for a polymer-supported olefin metathesis catalyst. A polymer-anchored carbene precursor was prepared by coupling an alkoxide to a cross-linked polystyrene Merrifield-type resin. Subsequently, the desired polymer-bound carbene complex was formed by thermolytically induced elimination of ferf-butanol while heating the precursor resin in the presence of the desired transition metal fragment (Scheme 8.30). 

Polymer-bound trifluoromethyl aryl ketone 42 was prepared by attaching 4-(trifluoroacetyl)benzoic acid to a suitably functionalized resin and used as a catalyst in Oxone-mediated epoxidations.64 The reactions proceed by in situ generation of the polymer-supported (trifluoromethyl)-dioxirane. A series of epoxides was formed in good to excellent yield. 

The capture of 4,6-dichloro-2-(methylthio)pyrimidine (8) was performed in DMF with diisopropylethylamine (DIPEA, Huenig s base) as a base and tetrabutylammonium bromide as a catalyst at 90°. The substitution of the remaining chlorine atom on the polymer-bound scaffold requires harsher conditions. Thus the immobilized 6-chlorothiomethylpyrimidine (9) could be substituted with aliphatic amines in neat amine at 140°. The coupling with anilines could be afforded consistently only by using KO Bu as base and [18]crown-6. Also, the use of Pd catalysts gave positive results, but failures were observed occasionally. Finally, the substitution of the thiomethyl group in resin-bound 2-(methylthio)pyrimidine-4,6-diamines... 

---