Enamines Vilsmeier-Haack reaction

At about the same time, Nicolaou and Chen et al. independently reported the synthesis of haplophytine [85]. Retrosynthetically, haplophytine was envisioned by a sequence of Suzuki-Miyaura Coupling, Vilsmeier-Haack reaction, and radical cyclization from indole 205 and vinyl iodide 206. The left-hand domain 205 could arise through the oxidative skeletal rearrangement of enamine 207, which could be obtained from the oxidative coupling of tetrahydro-jS-carboline 208 and diphenol 209 (Scheme 37). 

TL5981>. The proposed mechanism involves the oxidation of the amine to an imine, tautomerization to an enamine, and a sequence of nucleophilic attacks on the pyridazine rings followed by oxidation steps. The oxidant of choice is (bispyridine)silver permanganate <1982TL1847>, which is easily prepared, mild in action, and is soluble in organic media. If R1 = H in the product 77, electrophilic substitution (e.g., bromination, nitration, Mannich, and Vilsmeier-Haack-Arnold reactions) occurs at this position. 

Figure 6.12 shows that carboxylic acids can also be converted into carboxylic chlorides without releasing HC1. This is possible when carboxylic acids are treated with the chloro-enamine A. First the carboxylic acid adds to the C=C double bond of this reagent electrophilically (mechanism Figure 3.40, see also Figure 3.42). Then, the addition product B dissociates completely to give the ion pair C it constitutes the isopropyl analog of the Vilsmeier-Haack intermediate B of the DMF-catalyzed carboxylic chloride synthesis of Figure 6.11. The new Vilsmeier-Haack intermediate reacts exactly like the old one (cf. previous discussion) The chloride ion undertakes an SN reaction at the carboxyl carbon. This produces the desired acid chloride and isobutyric N,N-dimethylamide.

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