Polymer-supported reagent

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 polymer-supported superbase 30 was developed and used for the deprotonation and alkylation of weakly acidic nitrogen heterocycles such as indoles, phthalazinones, and pyrazoles.46 The diagram below illustrates the use of superbase 30 to alkylate a weakly basic pyrazole NH after acylation or alkylation of the more nucleophilic piperidine NH. Ami-nomethyl resin 1 was added after each step to sequester excess alkyl and/or acyl halide from the solution phase. 

A polymer-bound guanidine base 31 has been used for the formation of aryl ethers from suitable phenols and alkyl halides. In addition to serving as a base to affect deprotonation, reagent 31 also acts as a sequestering agent for excess starting phenol (reaction 11).26 

Polymeric Reagents that Mediate Condensation Reactions 

The PEG3400-linked triarylphosphine 33 was developed as a liquid-phase polymeric reagent for use in Staudinger and Mitsunobu reactions.48 Precipitation of the PEG polymer with cold diethyl ether, filtration, and evaporation afforded the purified products. 

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One widely used method of formation of protected compounds involves polymer-supported reagents, with the advantage of simple workup by filtration and automated syntheses, especially of polypeptides. Polymer-supported reagents are used to protect a terminal — COOH group as a polymer-bound ester (RCOOR —( ) during peptide syntheses, to protect primary alcohols as... 

S. Bhattacharyya, Polymer-supported reagents and catalysts Recent advances in synthetic applications. Comb Chem High Throughput Screening 3 65-92 2000. 

Organic dyes which are not complexed or are salts of metals are included in Chapter 4 (use the CAS Registry Numbers to find them). Commercially available polymer supported reagents are indicated with under the appropriate reagent. 

Tetra-n-propylammonium perruthenate (TPAP, tetrapropyl tetraoxoruthenate) [114615-82-6] M 351.4, m 160"(dec). It is a strong oxidant and may explode on heating. It can be washed with aq n-propanol, then H2O and dried over KOH in a vac. It is stable at room temp but best stored in a refrigerator. It is sol in CH2CI2 and MeCN. [Dengel et al. Transition Met Chem 10 98 1985 Griffith et al. J Chem Soc, Chem Commun 1625 1987.] Polymer supported reagent is available commercially. 

Polymer supported reagents, catalysts, protecting groups, and mediators can be used in place of the corresponding small molecule materials (Sherrington, 1991 Sundell and Nasman, 1993). The reactive species is tightly bound to a macromolecular support which immobilizes it. This generally makes toxic, noxious, or corrosive materials much safer. The use of polystyrene sulfonic acid catalyst for the manufacture of methyl r-butyl... 

Amos prepared his polymer-supported reagent in two steps from commercially available polystyrene beads (bromination, then condensation with lithium diphenylphosphide). He found that a useful range of sulphoxides could be reduced effectively, in good yields and in a few hours, to give clean samples of sulphides. 

Two polymer-supported reagents have been developed for the oxidation of sulphoxides to sulphones these involve peracid groups150, and bound hypervalent metals activated by t-butyl hydroperoxide151,152. 

Polychloromethylsulphonylbiphenyls, mass spectra of 154, 155 Polyenes, synthesis of 771 Polymerization, of sulphoxides 846 Polymer-supported reagents 928 Polymorphonuclear leukocytes 854 Poly(olefin sulphonejs, radiolysis of 916-922 Polysulphones, radiolysis of 913 Population analysis 14, 15, 21, 22 Propargylic sulphenates, rearrangement of 736-739... 

A solid-phase Diels-Alder reaction that uses polymer-supported reagents has recently attracted considerable attention and its use is expanding rapidly. 

Synthesis of Heterocycles Using Polymer-Supported Reagents under Microwave Irradiation... 

Synthesis of Heteroq cles Using Polymer-Supported Reagents... 

Scheme 3 Selected syntheses of heterocycles using polymer-supported reagents...

Heterocyclic compounds are of great interest to the pharmaceutical industry, as they make up most of the known pharmacophores. As a result, a number of libraries of various heterocycles have been prepared using polymer-supported reagents. While an exhaustive list of all the heterocychc cores that have been prepared using PSRs is beyond the scope of this chapter, some selected examples are depicted in Scheme 3. 

In this section, we will review the application of the combination of polymer-supported reagents and/or scavengers with microwave irradiation to the syn-... 

From a medicinal chemist s point of view, oxadiazoles are among the most important heterocycles as they are one of the most commonly used bioisosters for amide and ester groups [67]. As such it is hardly surprising that the two regioisomeric oxadiazole scaffolds received the most interest in the field of microwave-assisted synthesis using polymer-supported reagents. 

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