Catalysis continued intramolecular

The ruthenium catalyst system, 14, shown in Fig. 3, also carries out ADMET condensation chemistry, albeit with higher concentrations being required to achieve reasonable reaction rates [32]. The possibility of intramolecular compl-exation with this catalyst influences the polymerization reaction, but nonetheless, ruthenium catalysis has proved to be a valuable contributor to overall condensation metathesis chemistry. Equally significant, these catalysts are tolerant to the presence of alcohol functionality [33] and are relatively easy to synthesize. For these reasons, ruthenium catalysis continues to be important in both ADMET and ring closing metathesis chemistry. 

New synthetic methods for benzodiazepine synthesis involving Ugi-type multicomponent/post-Ugi cyclization reactions continue to be of interest. Ugi reactions of indole-2-carboxaldehydes, isocyanides, amines, and 2-iodobenzoic acid derivatives led to intermediates which, with copper(I) catalysis, underwent intramolecular indole N-arylation to produce indolo-fused benzodiazepinones, such as 134 (13CC2894). 2-Azido-benzaldehyde, isocyanides, propargylamines, and nitrophenols underwent Ugi-type reaction, Smiles-type rearrangement, and intramolecular azide-alkyne cyclization to afford triazolo-fused benzodiazepinones such as 135... 

There is little effect of micelles upon the rate of an intramolecular nucleophilic reaction. Micelles of hexadecyltrimethylammonium bromide catalyse, by factors of 10 —10, the arenesulphinate anion-induced hydrolysis of 4-tolylsulphonyl-methyl perchlorate. There is no relationship between the rate acceleration and hydro-phobicity of the sulphinate anion and catalysis is attributed to the concentration of the reactants in the micellar phase.The rate constants for the reaction of nucleophiles with carbonium ions and those for the addition of cyanide ion to the A -alkylpyridinium ions are similar in the micellar and aqueous phases, and the rate enhancement is due to the concentration of reactants in the micellar pseudophase. Similarly, although micellar catalysed dephosphorylation by nucleophiles may show rate enhancements of up to 4 x 10 -fold, the second-order rate constants may be slightly smaller in the micellar pseudophase lowing to its lower polarity. However, the reaction of fluoride ion with 4-nitrophenyldiphenyl phosphate is very rapid in micelles of cetyltrimethylammonium fluoride, but the rate constant continues to increase when the substrate is fully bound with increasing cetyltrimethylammonium fluoride or sodium fluoride. The failure of the micellar pseudophase model is also apparent in the reaction of hydroxide ion with 2,4-dinitrochlorobenzene. It is suggested that reaction occurs between reactants in the aqueous and micellar pseudophases and also between hydroxide ion in water and substrate in the micelle. ... 

The cyclization kinetics of 11 model l-[2-(methoxycarbonyl)phenyl]-3-(2-substitut-ed phenyl)triazenes (177) have been examined in aqueous methanolic buffer solutions at various pH values. 3-(2-Substituted phenyl)benzo[fi ][l,2,3]triazin-4(3 f)-ones (178) were identified as the cyclization products. The log fcobs vs pH plot was linear with a slope of unity. The assumed and confirmed Bac2 mechanism involving specific base catalysis begins by deprotonation of the triazene giving rise to the conjugate base, continues with formation of a tetrahedral intermediate, and ends with elimination of the methanolate ion (Scheme 32). Desilylation with methanolic HCl of the substituted anilide (179), a compound formed by a Ugi reaction, led to a facile intramolecular conversion to an ester (180). This reaction was the key step in a... 

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