Indoles coupling reactions

Lithiation at C2 can also be the starting point for 2-arylatioii or vinylation. The lithiated indoles can be converted to stannanes or zinc reagents which can undergo Pd-catalysed coupling with aryl, vinyl, benzyl and allyl halides or sulfonates. The mechanism of the coupling reaction involves formation of a disubstituted palladium intermediate by a combination of ligand exchange and oxidative addition. Phosphine catalysts and salts are often important reaction components. 

Indoles with carbocyclic halogen or triflate substituents are potential starting materials for vinylation, arylation and acylation via palladium-catalysed pro-cesses[l]. Indolylstannanes. indolylzinc halides and indolylboronic acids are also potential reactants. The principal type of substitution which is excluded from such coupling reactions is alkylation, since saturated alkyl groups tend to give elimination products in Pd-catalysed processes. 

Transition-Metal Catalyzed Cyclizations. o-Halogenated anilines and anilides can serve as indole precursors in a group of reactions which are typically cataly2ed by transition metals. Several catalysts have been developed which convert o-haloanilines or anilides to indoles by reaction with acetylenes. An early procedure involved coupling to a copper acetyUde with o-iodoaniline. A more versatile procedure involves palladium catalysis of the reaction of an o-bromo- or o-trifluoromethylsulfonyloxyanihde with a triaLkylstaimylalkyne. The reaction is conducted in two stages, first with a Pd(0) and then a Pd(II) catalyst (29). 

Coupling reactions of indole-3-acetic acid derivatives have also p ovided convenient routes to indolo[2,3-a]carbazoles (Scheme 5). An iodine-p-omoted coupling... 

Genkina et al. (1979, 1981, 1985) investigated azo coupling reactions of indoles with fused benzo and benzothiopheno rings, namely 4,5- and 6,7-benzindole, 4,5,6,7-dibenzindole (12.42), indolo[6,5]-, -[4,5]-, and -[5,4]-benzo[Z ]thiophene (12.43 to 12.45). Arenediazonium ions reacted with all these indole derivatives at the 3-position. 

AT-acetyltryptamines could be obtained via microwave-assisted transition-metal-catalyzed reactions on resin bound 3-[2-(acetylamino)ethyl]-2-iodo-lH-indole-5-carboxamide. While acceptable reaction conditions for the application of microwave irradiation have been identified for Stille heteroaryla-tion reactions, the related Suzuki protocol on the same substrate gave poor results, since at a constant power of 60 W, no full conversion (50-60%) of resin-bound 3-[2-(acetylamino)ethyl]-2-iodo-lH-indole-5-carboxamide could be obtained even when two consecutive cross-coupling reaction cycles (involving complete removal of reagents and by-products by washing off the resin) were used (Scheme 36). Also under conventional heating at 110 °C, and otherwise identical conditions, the Suzuki reactions proved to be difficult since two cross-coupling reaction cycles of 24 h had to be used to achieve full conversion. 

C-TMS protection of the alkyne provided acceptable yields of 3-substituted indole as long as the hydroxy group was protected with a stable group. Purple colored impurities, one of which has been identified as azulene 45, were seen in both coupling reactions using C-TMS-alkynes such as 36 and 40d (Scheme 4.9). The azulene was presumably formed through the dimerization of acetylenes... 

By-product generation with TMS-alkynes and the sluggish coupling rate with TBDMS-alkynes rendered the triethylsilyl (TES)-alkyne 40a the best reactant for the coupling reaction. Indeed, C-protection with the TES group gave indole 41a in 80% yield and also provided sufficient hydrolytic stability and satisfactory reaction kinetics for use in large scale synthesis. 

Eventually, indole acetic acid 2 was prepared from iodoaniline 28 and propargyl alcohol derivative 61 via the newly developed coupling reaction followed by a cyanide displacement-hydrolysis sequence, as shown in Scheme 4.16. 

Scheme 4.18 Coupling reaction using amines as base-formation of 2-methyl-indole.

This new impurity proved to be derived from the Pd-catalyzed oxidation of DIPA to the enamine via P-hydride elimination. In fact, mixing Pd(OAc)2 with DIPA in DMF-d7 readily formed Pd black along with two species, primary amine and acetone, presumably derived from the enamine through hydrolysis. The resulting enamine or acetone then underwent a coupling reaction with iodoaniline 28. Heterocyclization through the arylpalladium(II) species provided 2-methyl indole 71, as shown in Scheme 4.19. 

The Fukuyama indole synthesis involving radical cyclization of 2-alkenylisocyanides was extended by the author to allow preparation of2,3-disubstituted derivatives <00S429>. In this process, radical cyclization of 2-isocyanocinnamate (119) yields the 2-stannylindole 120, which upon treatment with iodine is converted into the 2-iodoindole 121. These N-unprotected 2-iodoindoles can then undergo a variety of palladium-catalyzed coupling reactions such as reaction with terminal acetylenes, terminal olefins, carbonylation and Suzuki coupling with phenyl borate to furnish the corresponding 2,3-disubstituted indoles. 

A concise method for the synthesis of the 5-substituted azepino[3,4-b]indol-l-ones 37 (eg. R = Bn, R1 = Ph) has been described, based on the Pd-mediated cross coupling reactions of azepino[3,4-b]indol-5-yl trifluoromethanesulfonates eg. 36. These latter compounds were accessed in turn from the corresponding azepino[3,4-i>]indole-l,5-dione <00T4491>. 

The necessity of the presence of two nitrogen atoms in the azole molecule for N, C -coupling reactions is exemplified by indole (see Eq. (3)). Neither indole nor... 

Another Suzuki coupling reaction was described by Zhang et al., to produce arylindoles 116a and b, using solid-phase synthesis [76]. The synthesis was achieved by palladium-mediated coupling/intramolecular indole cycli-zation of resin-bound 2-trimethylsilylindole 117, Scheme 29. 

Another series of COX-2 inhibitors was described by Hu et al., and the key step in this reaction is the construction of the indole skeleton by the Mc-Murry coupling reaction [77]. The chemistry described in this paper is shown... 

The 2,3-substituted indols are formed via a palladium-catalyzed coupling reaction of aryl halide, o-alkenylphenyl isocyanide, and amine (Equation (122)).481 Oxidative addition of an aryl halide, insertion of both the isonitrile and alkene moieties of o-alkenylphenyl isocyanide, and 1,3-hydrogen migration may form a 7r-allylpalladium species, which is then attacked by an amine to afford an indol. 

Of all the palladium-catalyzed coupling reactions, the Kumada coupling has been applied least often in indole chemistry. However, this Grignard-Pd cross-coupling methodology has been used to couple l-methyl-2-indolylmagnesium bromide with iodobenzene and a-bromovinyltrimethylsilane to form l-methyl-2-phenylindole and l-methyl-2-(l-trimethyl-... 

Abell utilized a Suzuki cross-coupling reaction on resin 153. Subsequent acid treatment effected cyclization to indole 154, which was readily cleaved with amines and alcohols to form potential libraries of amides and esters, respectively [162],... 

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