Anhydrides, reductive coupling with activated

Synthesis of left-hand segment began with 7-benzyloxyindole 197. A Vilsmeier-Haack formylation followed by condensation afforded nitroalkene 198. Reduction, acylation with succinic anhydride, and subsequent Bischler-Napieralski cyclization provided dihydro-p-carboline 199. Noyori asymmetric reduction of 199, further treatment with A-iodosuccinimide, followed by activation with silver triflate in the presence of dimethoxy-N,N-diallylaniline furnished the desired coupling product 200. Subsequent saponification and cyclization via a ketene intermediate gave the rearrangement precursor 201. Oxidative skeletal rearrangement initiated by m-CPBA followed by removal of the Fmoc group and conversion of the aniline to the hydrazine furnished Fischer indole precursor 202 (Scheme 35). 

The convergent synthesis of these compounds is rather simple. On the one side, the required a-keto ester may be synthesised from diethyl oxalate by a Grignard reaction. On the other side, alanine or trifluoroacetyllysine is coupled with proline via the oxazolidine-2,5-dione (the so-called Leuchs anhydride ). The two halves are combined by reductive amination. The diastereoselectivity of the hydrogenation is dependent on the choice of catalyst. With Raney nickel, the diastereoselectivity lies in case of enalapril at 87 13 and for Iisinoprii at 95 5 in favour of the desired diastereomers. In the case of Iisinoprii, there follows a final hydrolysis of the ester and amide function. The active material is ultimately purified by crystallisation. 

A variety of terminal functional groups and their chemical transformations on SAMs have been examined for example, (i) olefins—oxidation [23,24,131,132], hydroboration, and halogenation [23,24] (ii) amines—silyla-tion [145,146], coupling with carboxylic acids [22,146], and condensation with aldehydes [22,147] (iii) hydroxyl groups—reactions with anhydrides [148,149], isocyanates [150], epichlorohydrin [151], and chlorosilanes [152] (iv) carboxylic acids—formation of acyl chlorides [153], mixed anhydrides [154], and activated esters [148,155] (v) carboxylic esters—reduction and hydrolysis [156] (vi) thiols and sulfides—oxidation to generate disulfides [157-159] and sulfoxides [160] and (vii) aldehydes—condensation with active amines [161], Nucleophilic... 

The thiazine dyes used in the preparation of this type of leuco are obtained through oxidative coupling of phenothiazine with an active methylene compound or an aniline. The reduction of the dye 23 with zinc powder in acetic acid is straightforward.9 Treatment of the leuco 24 with acetic anhydride at 40°C yields a more air stable leuco 25.9 Addition of arylsulfinic acid to thiazine dyes such as 26 produces directly leuco dyes such as 27.Sb... 

The reaction sequence in the vinylation of aromatic halides and vinyl halides, i.e. the Heck reaction, is oxidative addition of the alkyl halide to a zerovalent palladium complex, then insertion of an alkene and completed by /3-hydride elimination and HX elimination. Initially though, C-H activation of a C-H alkene bond had also been taken into consideration. Although the Heck reaction reduces the formation of salt by-products by half compared with cross-coupling reactions, salts are still formed in stoichiometric amounts. Further reduction of salt production by a proper choice of aryl precursors has been reported (Chapter III.2.1) [1]. In these examples aromatic carboxylic anhydrides were used instead of halides and the co-produced acid can be recycled and one molecule of carbon monoxide is sacrificed. Catalytic activation of aromatic C-H bonds and subsequent insertion of alkenes leads to new C-C bond formation without production of halide salt byproducts, as shown in Scheme 1. When the hydroarylation reaction is performed with alkynes one obtains arylalkenes, the products of the Heck reaction, which now are synthesized without the co-production of salts. No reoxidation of the metal is required, because palladium(II) is regenerated. 

Y asuharu Yoshimi and Minoru Hatanaka of the University of Fukui have described (Chem. Comm. 2007, 5244) a convenient procedure for the reductive decarboxylation of acids such as 21 to the corresponding alkane 22. Teruaki Mukaiyamaofthe Kitasato Institute, Tokyo has developed (Chemistry Lett. 2007, 36,1456) a simple protocol for the activation of carboxylic acids for amide formation. DMAP-mediated coupling of the acid with 25 gave the mixed anhydride, which combined efficiently with the amine 24 to give the amide 26. 

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