Polymer-Supported Substrates

Polymer-supported reactants are most useful for cases where reactant byproducts would otherwise be difficult to sequester. Recycling of the 

Several polymeric acyl-transfer reactants have been used to give am-ide/ester products in the solution phase. The excess polymer-bound acyl-transfer reactants and polymer-bound nucleofuge byproducts are easily removed after completion of the reactions. One such application involved the activated nitrophenyl esters 25 (reaction 8).40 A mixture of 10 acid chlorides was converted to an equimolar mixture of 10 amide products a potent preemergent herbicide was discovered using this parallel synthetic approach.41 

Polymer-bound active esters 26 were prepared from a 1-hydroxyben-zotriazole (HOBt) functionalized polymer and carboxylic acids in the presence of tripyrrolidinyl-bromophosphonium hexafluorophosphate (Py- 

These active esters react smoothly with amines at room temperature (reaction 9).42 Similarly, supported oximino esters 2743 and hydroxamic esters 2844 undergo facile acyl transfer reactions with amines at room temperature (reaction 10). The spent activating agent can be regenerated many times (by acylation with the appropriate acid chloride) without appreciable loss in activity. 

A novel thiophenoxy 4-nitrophenylcarbonate-linked resin has been used to generate isocyanates in solution phase through the intermediacy of a resin-bound carbamate 29. The released isocyanates could be trapped with amines to form substituted ureas.45 

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The group of Botta demonstrated the feasibility of their microwave-assisted iodi-nation protocol (see Scheme 6.143 d) toward a polymer-supported substrate [68], An appropriate pyrimidinone attached to conventional Merrifield polystyrene resin was suspended in N,N-dimethylformamide, treated with 2 equivalents of N-iodosuccini-mide (NIS), and subjected to microwave irradiation for 3 min. Treatment of the polymer-bound intermediate with OXONE released the desired 5-iodouracil in almost quantitative yield (Scheme 7.57). 

An inverted system based on the C02-soluble catalyst Pd(OAc)2/PtBu3 has been utilized for Suzuki-coupling of resin-bound substrates [33], The use of scC02 with polymer-supported substrates seems highly attractive owing to the known plasticizing... 

Polymer-supported reagents differ from polymer-supported substrates in that the former mediate a reaction rather than becoming an integral part of the product. A major attribute of tethered reagents is that both the reagent and the reagent byproduct can be directly filtered away from solution-phase products. 

The reactivity of a building block with different polymer-supported substrates can be evaluated in one reaction vessel. 

Price et al. (Table 8, entry 44) [496] investigated several polystyrene-bound, proli-nol-based chiral auxilaries. The authors performed stereoselective a-allylation with support-bound, hydrolytically more stable propanylamide. The allylated product was then cleaved from the support by enantioselective, linker-induced iodolactoni-zation. The attachment sites of the chiral auxiliary had a profound impact on the stereoselectivity, which was found to be higher than with solution-phase chiral auxiharies. The highest enantioselectivity was achieved with a pseudo C2-symmet-ric auxihary. As solvation effects of polymer-supported substrates are currently still difficult to predict, it is hard to explain why in this case solid-support-bound chiral auxiliaries gave higher enantioselectivities than their solution analogs. 

An interesting development of this research is the preparation of polymer-supported FITS reagent from bis(trifluoroacetoxy)iodoperfluoroalkanes and Nafion-H [145]. FITS-Nafion reacts with organic substrates that react to usual FITS reagents, but the products of the perfluoroalkylation reaction can be separated easily from the insoluble resin by filtration [145]... 

Allylic alcohols can be converted to epoxy-alcohols with tert-butylhydroperoxide on molecular sieves, or with peroxy acids. Epoxidation of allylic alcohols can also be done with high enantioselectivity. In the Sharpless asymmetric epoxidation,allylic alcohols are converted to optically active epoxides in better than 90% ee, by treatment with r-BuOOH, titanium tetraisopropoxide and optically active diethyl tartrate. The Ti(OCHMe2)4 and diethyl tartrate can be present in catalytic amounts (15-lOmol %) if molecular sieves are present. Polymer-supported catalysts have also been reported. Since both (-t-) and ( —) diethyl tartrate are readily available, and the reaction is stereospecific, either enantiomer of the product can be prepared. The method has been successful for a wide range of primary allylic alcohols, where the double bond is mono-, di-, tri-, and tetrasubstituted. This procedure, in which an optically active catalyst is used to induce asymmetry, has proved to be one of the most important methods of asymmetric synthesis, and has been used to prepare a large number of optically active natural products and other compounds. The mechanism of the Sharpless epoxidation is believed to involve attack on the substrate by a compound formed from the titanium alkoxide and the diethyl tartrate to produce a complex that also contains the substrate and the r-BuOOH. ... 

A polymer-supported version of our optimal ligand was also developed [52]. Its preparation involves attachment of aziridine carbinols to polymer-bound triphenylchloromethane (Scheme 40). This polymer-bound ligand 53 was almost equally effective in the enantioselective addition of diethylzinc to aromatic and aliphatic aldehydes with ee s ranging from 77-97% for the latter type of substrate [52]. It is of practical interest that this polymer-supported ligand could be reused without losing much of its efficiency. 

The artificial lipid bilayer is often prepared via the vesicle-fusion method [8]. In the vesicle fusion process, immersing a solid substrate in a vesicle dispersion solution induces adsorption and rupture of the vesicles on the substrate, which yields a planar and continuous lipid bilayer structure (Figure 13.1) [9]. The Langmuir-Blodgett transfer process is also a useful method [10]. These artificial lipid bilayers can support various biomolecules [11-16]. However, we have to take care because some transmembrane proteins incorporated in these artificial lipid bilayers interact directly with the substrate surface due to a lack of sufficient space between the bilayer and the substrate. This alters the native properties of the proteins and prohibits free diffusion in the lipid bilayer [17[. To avoid this undesirable situation, polymer-supported bilayers [7, 18, 19] or tethered bilayers [20, 21] are used. 

Initiator (233), and a polymer-supported analog,641 are commercially available and have found widespread use in the ring-closing metathesis (RCM) and ROMP of functionalized substrates. In addition, water-soluble variants such as (234) and (235) have been synthesized using aliphatic ionic phosphines and employed in aqueous media.642-645... 

As a suitable model reaction, the coupling of various substituted carboxylic acids to polymer resins has been investigated by Stadler and Kappe (Scheme 7.8) [28]. The resulting polymer-bound esters served as useful building blocks in a variety of further solid-phase transformations. In a preliminary experiment, benzoic acid was attached to Merrifield resin under microwave conditions within 5 min (Scheme 7.8 a). This functionalization was additionally used to determine the effect of micro-wave irradiation on the cleavage of substrates from polymer supports (see Section 7.1.10). The benzoic acid was quantitatively coupled within 5 min via its cesium salt utilizing standard glassware under atmospheric reflux conditions at 200 °C. 

In a recent study, another method for microwave-assisted heterocycle synthesis leading to a small set of imidazole derivatives has been reported [54], These pharmaceutically important scaffolds were synthesized utilizing polymer-bound 3-N,N-(dimethylamino)isocyanoacrylate. This polymer support was easily prepared by treatment of [4-(bromomethyl)phenoxy]methyl polystyrene with a twofold excess of the appropriate isocyanoacrylate potassium salt in N,N-dimethylformamide (Scheme 7.37). The obtained intermediate was subsequently treated with N,N-di-methylformamide diethyl acetal (DMFDEA) in a mixture of tetrahydrofuran and ethanol to generate the desired polymer-bound substrate. 

The substrates were admixed with 50 mol% of copper(I) chloride and small amounts of l-(2-propyl)-3-methylimidazolium hexafluorophosphate (pmimPF6) in dioxane. The mixture was heated to 110 °C within 2 min and kept at this reaction temperature for an additional 1 min. After cooling to room temperature, the product was rapidly released from the polymer support employing 20% trifluoroacetic acid (TFA) in dichloromethane, furnishing the corresponding bis-TFA salt in moderate yield. 

Several microwave-assisted protocols for soluble polymer-supported syntheses have been described. Among the first examples of so-called liquid-phase synthesis were aqueous Suzuki couplings. Schotten and coworkers presented the use of polyethylene glycol (PEG)-bound aryl halides and sulfonates in these palladium-catalyzed cross-couplings [70]. The authors demonstrated that no additional phase-transfer catalyst (PTC) is needed when the PEG-bound electrophiles are coupled with appropriate aryl boronic acids. The polymer-bound substrates were coupled with 1.2 equivalents of the boronic acids in water under short-term microwave irradiation in sealed vessels in a domestic microwave oven (Scheme 7.62). Work-up involved precipitation of the polymer-bound biaryl from a suitable organic solvent with diethyl ether. Water and insoluble impurities need to be removed prior to precipitation in order to achieve high recoveries of the products. 

The soluble polymer support was dissolved in dichloromethane and treated with 3 equivalents of chloroacetyl chloride for 10 min under microwave irradiation. The subsequent nucleophilic substitution utilizing 4 equivalents of various primary amines was carried out in N,N-dimethylformamide as solvent. The resulting PEG-bound amines were reacted with 3 equivalents of aryl or alkyl isothiocyanates in dichloromethane to furnish the polymer-bound urea derivatives after 5 min of micro-wave irradiation (Scheme 7.75). After each step, the intermediates were purified by simple precipitation with diethyl ether and filtration, so as to remove by-products and unreacted substrates. Finally, traceless release of the desired compounds by cyclative cleavage was achieved under mild basic conditions within 5 min of micro-wave irradiation. The 1,3-disubstituted hydantoins were obtained in varying yields but high purity. 

The polymer-supported 5-chloromethyl-l,2,4-oxadiazole 162 undergoes easy reaction with primary amines to give the 5-aminomethyl oxadiazoles 163, which serve as excellent substrates for the synthesis of amides or sulfonamides 164 (Scheme 21 - yields not reported) <1999TL8547>. 

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