Palladium complexes ester hydrolysis

The use of a lipophilic zinc(II) macrocycle complex, 1-hexadecyl-1,4,7,10-tetraazacyclododecane, to catalyze hydrolysis of lipophilic esters, both phosphate and carboxy (425), links this Section to the previous Section. Here, and in studies of the catalysis of hydrolysis of 4-nitrophenyl acetate by the Zn2+ and Co2+ complexes of tris(4,5-di-n-propyl-2 -imidazolyl)phosphine (426) and of a phosphate triester, a phos-phonate diester, and O-isopropyl methylfluorophosphonate (Sarin) by [Cu(A(A(A/,-trimethyl-A/,-tetradecylethylenediamine)l (427), various micellar effects have been brought into play. Catalysis of carboxylic ester hydrolysis is more effectively catalyzed by A"-methylimidazole-functionalized gold nanoparticles than by micellar catalysis (428). Other reports on mechanisms of metal-assisted carboxy ester hydrolyses deal with copper(II) (429), zinc(II) (430,431), and palladium(II) (432). 

Hydrolysis of the ester forms adipic acid, used to manufacture nylon—6. Carbonylations of nitroaromatics are used to synthesize an array of products including amines, carbamates, isocyanates, ureas and azo compounds. These reactions are catalyzed by iron, ruthenium, rhodium and palladium complexes. For example, carhonylation of nitrobenzene in the presence of methanol produces a carbamate ... 

The palladium(II)-promoted hydrolysis of methyl glycylglycinate and isopropyl glycylglycinate has been investigated over a temperature range.80 Complexes of type (22) are formed in which the amino, deprotonated amide and alkoxycarbonyl groups act as donors. Hydrolysis by both H20 and OH ion is observed. Base hydrolysis of the coordinated peptide esters is ca. 105-fold faster than the unprotonated peptide esters. 

The n-complex of the alkene and Pd(II) allows nucleophilic attack by the amide on the nearer end and in a cis fashion because the nucleophile is tethered to the alkene by only two carbon atoms. Nucleophilic attack and elimination of palladium(O) occur in the usual way. The removal of the C02Bn group would normally be by hydrogenolysis but in this case ester hydrolysis by, say, HBr treatment would be preferred to avoid reduction of the alkene. The free acid decarboxylates spontaneously. 

The a-keto amides are less susceptible to hydrolysis and preparation of a-keto esters and acids are preferable for synthesizing various derivatives thereof. Various aryl iodides and bromides can be converted into a-keto esters on reactions with alcohols and carbon monoxide in the presence of a base such as tertiary amines or potassium acetate with catalytic amounts of tertiary phosphine-coordinated palladium complexes (Eq. 11).[42]-[46] jjjgjj yields of a-keto esters can be achieved only when iodide substrates are used. Double carbonylation of aryl bromides to a-keto esters can be accomplished with difficulty at much slower rates. Alkyl and benzyl iodides give no double carbonylation products. 

A similar Nicolas-Pauson-Khand combination was used in a synthesis of the ketone analogue of biotin 7.98, required for biochemical studies (Scheme 7.25). In this case, the Nicholas reaction was intermolecular, between allyl thiol as the nucleophile and carbocation 7.94 generated from alcohol 7.93. The Pauson-Khand reaction was then between the dicobalt complexed alkyne 7.95 and the double bond from the thiol moiety. The Pauson-Khand reaction proceeded with no stereoselectivity, and the diastereoisomers had to be chromatographically separated at a later stage. The synthesis was completed by reduction of the alkene of cyclopentenone 7.96, without using palladium-catalysed hydrogenation due to the sulfide moiety, and ester hydrolysis. 

A number of recent studies have been carried out with palladium(II) complexes,85"87 of the types (18) and (19). These mixed ligand complexes are formed in solution by the addition of the a-amino acid ester to the corresponding diaqua species, for example [Pd(en)(OH2)2j2+. The kinetics of hydrolysis of the ester ligand in such mixed ligand complexes have been studied in detail. Nucleophilic attack by both OH- and OH2 occurs. Typical kinetic data are summarized in Table 15. 

Reactions of Pyrroles. 1,3-Di-t-butylpyrrole forms the first stable protonated pyrrole, the salt (104). Electrophilic substitution of pyrrole with MeaC or Me FC in the gas phase occurs mainly at the j3-position, as does nitration and Friedel-Crafts acylation of l-phenylsulphonylpyrrole2 Pyrrole-2,5-dialdehyde has been prepared by Vilsmeier-Haack formylation of the ester (105), followed by hydrolysis. A similar method has been used to convert the di-acetal (106) into pyrrole-2,3,5-tricarbaldehyde. AT-Benzoyl-pyrrole reacts with benzene in the presence of palladium(II) acetate to yield a mixture of l-benzoyl-2,5-diphenylpyrrole, the bipyrrolyl (107), and compound (108). Treating lithiated A-methylpyrrole with nickel(II) chloride results in the polypyrrolyls (109 = 0-4). 2-Aryl-1-methylpyrroles are obtained by cross-coupling of l-methylpyrrol-2-ylmagnesium bromide with aryl halides in the presence of palladium(0)-phosphine complexes. ... 

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