Aldehydes, polymer-bound, reactions

The polymer-bound catalysts A-C. (Table 31) are prepared by reaction of the corresponding amino alcohols with partially chloromethylated 1 -2% cross-linked polystyrene. In the case of A, the enantioselectivity of the addition of dialkylzincs to aldehydes is higher than with the corresponding monomeric ephedrine derivatives (vide supra). Interesting insights into the mechanism of the alkylation of aldehydes by dialkylzinc reagents can be obtained from the experi-... 

Supported Lewis acids are an interesting class of catalysts because of their operational simplicity, filterability and reusability. The polymer-bound iron Lewis-acid 53 (Figure 3.8) has been found [52] to be active in the cycloadditions of a, S-unsaturated aldehydes with several dienes. It has been prepared from (ri -vinylcyclopentadienyl)dicarbonylmethyliron which was copolymerized with divinylbenzene and then treated with trimethylsilyltriflate followed by THF. Some results of the Diels-Alder reactions of acrolein and crotonaldehyde with isoprene (2) and 2,3-dimethylbutadiene (4) are summarized in Equation 3.13. 

Allen (106) also studied cobalt hydroformylation with a polymer-bound catalyst. The polymer was formed from diphenyl-p-styrylphosphine cross-linked with divinylbenzene. 2-Hexene was the substrate, and reaction conditions were 175°C and 1500-3000 psi of 1/1 H2/CO. The product aldehyde was 55% linear, and the effluent product solution contained 20-50 ppm cobalt. 

Although of little general use under normal Wittig conditions, tetra-n-butyl-ammonium iodide aids the reaction between polymer-bound benzylphosphonium salts and aromatic aldehydes with yields generally >90% [17]. 

Starting material which, upon oxidation with PSP, gave aldehydes. These were in turn condensed with primary hydroxylamines, promoted by polymer-bound acetate, to produce nitrones. The nitrones assembled using either method then underwent 1,3-dipolar cyclo-addition reactions with various alkenes to give the corresponding isoxazolidines (Scheme 2.46 and 2.47). 

In another approach, a polymer-bound TEMPO-species, referred to as PIPO (polyamine immobilized piperidinyl oxyl), was derived by oxidation of commercially available Chimasorb 944, an oligomeric sterically hindered amine. Together with bleach as co-oxidant PIPO (12) afforded aldehydes and ketones in short reaction times and with yields from 80 to > 99% (Scheme 4.6) [70]. 

Recently it was found that the aldol reaction of silyl enol ethers with acetals or aldehydes is effectively promoted by a catalytic amount of trityl perchlorate to give the corresponding aldols in good yields (44,45). Polymer-bound trityl perchlorate also successfully catalyzed the aldol reaction (45). 

Vinyl triflates (10, 123).1 The most satisfactory conditions for preparation of vinyl triflates from carbonyl compounds using triflic anhydride and catalyzed by the pyridine 1 or the polymer-bound reagent 2 are discussed by Wright and Pulley. In the case of aldehydes, the reaction is best carried out in CHC13 or (CH2C1)2 at 50-70°, and results in a gem-bistriflate, which decomposes thermally to the vinyl triflate. These conditions, when applied to a ketone, particularly aldol-prone ones, are usually not useful. The preferred solvent is nonpolar (CClt) with a reaction temperature of about 50°. In addition, the Tf20 should be freshly distilled from P205. 

Polymer-bound P-lactams have been prepared via the ester enolate imine condensation route <02JOC8034>. On the other hand, an efficient asymmetric synthesis of 2-azetidinones was accomplished when chiral acid chlorides or chiral aldehydes were used in the polymer-supported Staudinger reaction <02TA905>. 

Scavenger resins and polymer-bound reagents are routinely used to prepare medium-sized (500-1000 member) libraries. Polymer-bound isocyanates (9) and aldehydes (10) are used to remove amines from reaction mixtures, while polymer-bound thiols (11) are used to scavenge halides. 

Similarly, a novel one-pot microwave-assisted reaction has been described by Hulme and co-workers that enables the selective formation of 3-iminoaryl-imidazo[l,2-a]pyridines 19 and imidazo[l,2-a]pyridyn-3-ylamino-2-acetonitriles 20, in good yields. Reactions were performed in methanol by mixing a suitable a-aminopyridine, an aldehyde and trimethylsilylcyanide (TMSCN) with polymer-bound scandium triflate, to afford either product 19 or 20 (Scheme 16). Initially, the 3-iminoaryl-imidazo[l,2-a]pyridine 19, was observed as a minor side product (0-10%) during the pseudo-Ugi reaction affording the 3-aminoimidazo[l,2-a]pyridine 18. However, by increasing the aldehyde input to 2.2 equiv the reaction could be directed to the formation of 19 in moderate yields. Interestingly, low yields of... 

Aldehyde-tannin and aldehyde-anthocyanin condensation reactions result in polymer formation (Figure 1). These polymers may be responsible for haze formation in wine and the polymers may eventually precipitate out of solution (26). The polymerized tannins have different flavor properties than the monomeric starting units (21-29) and formation of anthocyanin polymers affects wine color. In addition, these reactions may result in a reduction of aldehyde flavors in the wine. These condensation reactions are discussed more fully in other chapters of this volume. The formation of strong covalent bonds between the aldehyde and the tannin or anthocyanin makes recovery of the bound aldehydes difficult. 

Solid-phase synthesis of substituted pyrazolones 550 from polymer-bound /3-keto esters 549 has been described (Scheme 68) <2001EJ01631>. Trisubstituted pyrazole carboxylic acids were prepared by reaction of polymer-bound arylidene- or alkylidene-/3-oxo esters with phenylhydrazines <1999S1961>. 2-(Pyrazol-l-yl)pyrimi-dine derivatives were prepared by cyclocondensation of ethyl acetoacetate and (6-methyl-4-oxo-3,4-dihydropyrimi-din-2-yl)hydrazine with aromatic aldehydes <2004RJC423>. Reactions of acylated diethyl malonates with hydrazine monohydrochloride in ethanol afforded 3,4-disubstituted-pyrazolin-5-ones <2002T3639>. Reactions of hydrazines with A -acetoacetyl derivatives of (45 )-4-benzyloxazolidin-2-one (Evans oxazolidinone) and (2R)-bornane-10,2-sultam (Oppolzer sultam) in very acidic media gave pyrazoles retaining the 3(5)-chiral moiety <1999S157>. 

A protocol involving the intermolecular cyclization between acetals and ureas has been developed to synthesize imidazolones on solid support. Reaction of polymer-bound glycerol 1148 with bromoacetaldehyde diethyl acetal gives the cyclic acetal bromide 1149. Amination followed by urea formation affords the resin-bound urea acetals 1150. The aldehydes released from the resin upon treatment with TFA immediately cyclize to give 2-imidazolones 1151 in good yields and purity (Scheme 279) <2002TL4571>. 

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