Amines acylation, polymer-supported

Weik and Rademann have described the use of phosphoranes as polymer-bound acylation equivalents [65]. The authors chose a norstatine isostere as a synthetic target and employed classical polymer-bound triphenylphosphine in their studies (Scheme 7.54). Initial alkylation of the polymer-supported reagent was achieved with bromoacetonitrile under microwave irradiation. Simple treatment with triethyl-amine transformed the polymer-bound phosphonium salt into the corresponding stable phosphorane, which could be efficiently coupled with various protected amino acids. In this acylation step, the exclusion of water was crucial. 

A variation of this method led to the generation of bis-benzimidazoles [81, 82], The versatile immobilized ortho-phenylenediamine template was prepared as described above in several microwave-mediated steps. Additional N-acylation exclusively at the primary aromatic amine moiety was achieved utilizing the initially used 4-fluoro-3-nitrobenzoic acid at room temperature (Scheme 7.72). Various amines were used to introduce diversity through nucleophilic aromatic substitution. Cyclization to the polymer-bound benzimidazole was achieved by refluxing for several hours in a mixture of trifluoroacetic acid and chloroform. Individual steps at ambient temperature for selective reduction, cyclization with several aldehydes, and final detachment from the polymer support were necessary in order to obtain the desired bis-benzimidazoles. A set of 13 examples was prepared in high yields and good purities [81]. 

In 1982 Cardillo used a three-step sequence involving two supported reagent systems to convert /i-iodoamines into amino alcohols (Scheme 2.23) [45]. Polymer-supported acetate ions were used for the substitution of the iodide which immediately underwent acyl transfer to the amine. The resulting compound (10) was directly treated with hydrochloric acid to cleave the amide and the free base was subsequently obtained from the reaction by treatment with a resin-bound carbonate. This was of particularly synthetic value because of the high water solubiHty of these amino alcohol compounds that would have made aqueous work-up challenging. 

Kinetic resolution with racemisation Enzymes versus whole organisms Desymmetrisation with lipases Immobilised enzymes in desymmetrisation Polymer-supported reagents and enzymes Effects of amines on lipases and esterases Other acylating enzymes Enzymatic Oxidation... 

N-Acylation, The polymer-supported base 1 adequately serves for use in the acylation of weakly nucleophilic amines. 

Based on a multi-component condensation approach related to the Doebner reaction,Gopalsamy et developed a solid-phase synthesis for this clinically useful pharmacophore. Thus, starting from Rink resin 65, acylation with the required N-Fmoc-amino acid 232 and deprotection with piperidine gave the polymer-supported amine 233 (90% yield) which was acylated with pyruvyl chloride (234). Immobilised pymvic amide 235 was refluxed with excess of preformed benzyUdene aniline 239 or alternatively condensed with an excess of an equimolecular mixture of aldehyde 236 and anilines 237. Cleavage of 238 with 45% TFA afforded compounds 240 in good yields and with high purities (>90%) (Scheme 4.3.5). 

Solid-phase scavenger methods are employed with increasing frequency as a prehminary reaction cleanup step in combinatorial chemistry, and have recently become commercially available (Argonaut, Calbiochem-Novabiochem, Varian, Alltech). lilly researchers first reported on this approach, employing sohd supported electrophiles and nucleophiles for reaction purification in acylation and alkylation reactions. Yield and purity values reported were 90-95% and 50-99%, respectively, for a library generated by reductive amination. Parke-Davis researchers achieved the removal of known reaction product impurities by the application of custom synthesized polymer supported reagents, specifically polystyrene-divinylbenzene supported derivatives of methylisocyanate and tm(2-aminomethyl)amine for cleanup of by-products resulting from urea, thiourea,sulfonamide,amide, and pyrazole libraries. 

Based on Mannich-type reactions of N-acryliminoacetates with silyl enol ethers, a new method for the preparation of N-acylated amino acid derivatives via nucleophilic addition to N-acrylimino ester has been developed using a polymer-supported amine and scandium catalysts (Scheme 12.5) [9]. Ethyl N-benzoyl-2-bromoglycine was used as a substrate. It could be readily converted to reactive N-acrylimino ester in situ by treatment with a base. Immobilizations of the amine and the scandium species into polymeric supports prevented loss of activity of the catalyst. The method is simple and provides a convenient method for the preparation of N-acrylated amino acid derivatives. 

PEG-supported organic moieties 3. The PEG-bound amines 3 were then treated with various electrophiles such as benzoyl chloride, morpholine carbonyl-chloride, phenyl isocyanate, and sulfonyl chloride at ambient temperature to give corresponding acylated products. Treatment of the acylated products with 1 % KCN/methanol resulted in efficient cleavage from the polymer support to give corresponding products 4 in 99% yield with 84-94% HPLC crude purity (9). 

A further application of the benzotriazole linker is the synthesis of fi-diketones 382. Polymer-supported benzotriazoles 371 were transformed into the corresponding azolides which were cleaved with various ketone hhio eno-lates to build diketones 382 [261]. Other cleavage reactions with nucleophiles should be possible as benzotriazole auxiliaries are often used as advantageous N, C-, S- and 0-acylating reagents [262]. A well-known application is the solid phase synthesis of unsymmetric ureas (R = NR2) with secondary amines as cleaving nucleophiles [258]. 

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