O-iodoanilines

In the reaction of aryl and alkenyl halides with 1,3-pentadiene (248), amine and alcohol capture the 7r-allylpalladium intermediate to form 249. In the reactions of o-iodoaniline (250) and o-iodobenzyl alcohol (253) with 1,3-dienes, the amine and benzyl alcohol capture the Tr-allylpalladium intermediates 251 and 254 to give 252 and 255[173-175]. The reaction of o-iodoaniline (250) with 1,4-pen tadiene (256) affords the cyclized product 260 via arylpalladiuni formation, addition to the diene 256 to form 257. palladium migration (elimination of Pd—H and readdition to give 258) to form the Tr-allylpalladium 259, and intramolecular displacement of Tr-allylpalladium with the amine to form 260[176], o-Iodophenol reacts similarly. 

Pyrrole derivatives are prepared by the coupling and annulation of o-iodoa-nilines with internal alkynes[291]. The 4-amino-5-iodopyrimidine 428 reacts with the TMS-substituted propargyl alcohol 429 to form the heterocondensed pyrrole 430, and the TMS is removed[292]. Similarly, the tryptophane 434 is obtained by the reaction of o-iodoaniline (431) with the internal alkyne 432 and deprotection of the coupled product 433(293]. As an alternative method, the 2,3-disubstituted indole 436 is obtained directly by the coupling of the o-alky-nyltrifluoroacetanilide 435 with aryl and alkenyl halides or triflates(294]. 

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). 

Substituted indoles can be prepared from o-bromo or o-iodoanilines by paHadium-cataly2ed cycli2ation of AJ-aHyl derivatives (31). 

Since the amine by-product formation was essentially derived from the reaction of an enamine or a ketone with iodoaniline, the direct use of a ketone as the substrate instead of an amine, would also be expected to yield the indole (Scheme 4.21). Indeed, we were gratified to find that direct condensation of o-iodoaniline 24 (77, R, = H) with cyclohexanone (in the presence of 5mol% Pd(OAc)2 and 3 equiv DAB CO as a base at 0.3 M and 105 °C afforded the tetrahydrocarbazole 81a in 77% yield with no other major impurities (Figure 4.4) [5], The use of DMF as a solvent is crucial to the success of this reaction other solvents such as acetonitrile and toluene were ineffective. 

Imines derived from o-iodoaniline and arenecarboxaldehydes react with internal arylalkynes and catalytic Pd(0) to afford isoindolo[2,l-a]indoles by a process that involves alkyne insertion, addition across the C=N double bond and substitution of the aromatic ring (Scheme 11).12 This process exhibits very... 

If one employs o-iodoaniline derivatives in this double insertion chemistry, 2-quinolones are generated in good yield after a basic work-up to remove the nitrogen protecting group (Scheme 14).15... 

A typical second step after the insertion of CO into aryl or alkenyl-Pd(II) compounds is the addition to alkenes [148]. However, allenes can also be used (as shown in the following examples) where a it-allyl-r 3-Pd-complex is formed as an intermediate which undergoes a nucleophilic substitution. Thus, Alper and coworkers [148], as well as Grigg and coworkers [149], described a Pd-catalyzed transformation of o-iodophenols and o-iodoanilines with allenes in the presence of CO. Reaction of 6/1-310 or 6/1-311 with 6/1-312 in the presence of Pd° under a CO atmosphere (1 atm) led to the chromanones 6/1-314 and quinolones 6/1-315, respectively, via the Jt-allyl-r 3-Pd-complex 6/1-313 (Scheme 6/1.82). The enones obtained can be transformed by a Michael addition with amines, followed by reduction to give y-amino alcohols. Quinolones and chromanones are of interest due to their pronounced biological activity as antibacterials [150], antifungals [151] and neurotrophic factors [152]. 

The synthesis of (5 5 5) fused heterocyclic compounds 7 <2001JOC412> has been achieved in 84% yield via annulation of internal alkynes by imines 287 derived from o-iodoaniline in the presence of palladium catalyst (Scheme 51). 

Palladium-catalyzed reactions of arylboronic acids have been utilized to craft precursors for constructing indole rings. Suzuki found that tris(2-ethoxyethenyl)borane (149) and catechol-derived boranes 150 readily couple with o-iodoanilines to yield 151, which easily cyclize to indoles 152 with acid [158]. Kumar and co-workers used this method to prepare 5-(4-pyridinyl)-7-azaindoles from 6-amino-5-iodo-2-methyl-3,4 -bipyridyl [159], A similar scheme with catechol-vinyl sulfide boranes also leads to indoles [160]. A Suzuki protocol has been employed by Sun and co-workers to synthesize a series of 6-aryloxindoles [161]. 

The combination of o-iodoaniline 205, tributyl-2-thienylstannane (206), and bisalkyne 207 provides oxindole 208 in the presence of a Wilkinson s catalyst/Pd(0) system [206]. 

Gronowitz adapted this technology to one-pot syntheses of indole-3-acetic acids and indole-3-pyruvic acid oxime ethers from A-BOC protected o-iodoanilines [328, 329]. Rawal employed the Pd-catalyzed cyclization of A-(o-bromoallyl)anilines to afford 4- and 6-hydroxyindoles, and a 4,6-dihydroxyindole [330], and Yang and co-workers have used a similar cyclization to prepare 8-carbolines 287 and 288 as illustrated by the two examples shown [331]. The apparent extraneous methyl group in 288 is derived from triethylamine. 

Ogasawara employed a Heck reaction of o-iodoaniline derivatives with dihydrodimethoxyfuran and vinylene carbonate to give intermediates that are readily cyclized to indoles with acid [381-383]. An example is shown below [381]. 

Similar Pd-catalyzed chemistry between o-iodoanilines and 1,3-dienes leading to 2-vinylindolines is also known, having been first described by Dieck and co-workers [398], This reaction, which is shown for the synthesis of 309, was discovered before Larock s work in this area. The same reaction with 1,3-cyclohexadiene gives the corresponding tetrahydrocarbazole in 70% yield. 

Larock extended this Pd-catalyzed diene heteroannulation to other dienes and anilines [399], including functionalized dienes leading to, for example, ketotetrahydrocarbazoles [400]. Back has employed 1-sulfonyl-l,3-dienes in this 2-vinylindoline synthesis [401], and the use of 1,3-dienes in constructing indolines has been adapted to the solid phase by Wang [402]. Interestingly, Larock has shown that the electronically-related vinylcyclopropanes undergo a similar cyclization with o-iodoanilines to form 2-vinylindolines, e.g., 310 [403, 404]. Vinylcyclobutane also reacts in a comparable manner. 

Prior to his work with internal alkynes, Larock found that o-thallated acetanilide undergoes Pd-catalyzed reactions with vinyl bromide and allyl chloride to give (V-acetylindole and N-acetyl-2-methylindole each in 45% yield [409]. In an extension to reactions of internal alkynes with imines of o-iodoaniline, Larock reported a concise synthesis of isoindolo[2,l-a]indoles 313 and 314 [410]. The regioselectivity was excellent with unsymmetrical alkynes. 

While the intramolecular Heck reaction has been widely used to synthesize indoles and benzofurans, not many applications have been found in the preparation of benzothiophenes because of the thiophilicity of the Pd(II) species. Pleixats and coworkers treated iodophenylsulfide 151, obtained from o-iodoaniline and crotyl bromide in two steps, with... 

The palladium complex of the dibenzofuran-based water-soluble tertiary phosphine 49 was found catalytically active for the internal Heck reaction of N-aUyl-o-iodoaniline in CH3CN/H2O l/l(Scheme 6.6) [21],... 

The anion-radical mechanism for these syntheses is based on the following facts. The reactions require photo- or electrochemical initiation. Oxygen inhibits the reactions totally, even with photoirradiation. Indoles are formed from o-iodoaniline only the meta isomer does not give rise to indole. Hence, the alternative aryne mechanism (cine-substitution) is not valid. What remains as a question is the validity of the ion-radical mechanism exclusively to the substitution of the acetonyl group for the halogen atom in o-haloareneamine or also for intramolecular condensation. 

Cyclocarbonylation of o-iodophenols 503 with isocyanates or carbodiimides and carbon monoxide in the presence of a catalytic amount of a palladium catalyst (tris(dibenzylideneacetone)dipalladium(O) Pd2(DBA)3) and l,4-bis(di-phenylphosphino)butane (dppb) resulted in formation of l,3-benzoxazine-2,4-diones 504 or 2-imino-l,3-benzoxazin-4-ones 505 (Scheme 94). The product yields were dependent on the nature of the substrate, the catalyst, the solvent, the base, and the phosphine ligand. The reactions of o-iodophenols with unsymmetrical carbodiimides bearing an alkyl and an aryl substituent afforded 2-alkylimino-3-aryl-l,3-benzoxazin-4-ones 505 in a completely regioselective manner <1999JOC9194>. On the palladium-catalyzed cyclocarbonylation of o-iodoanilines with acyl chlorides and carbon monoxide, 2-substituted-4f/-3,l-benzoxazin-4-ones were obtained <19990L1619>. 

When these CCH conditions were applied to o-iodonitrobenzene (1), cr iodoaniline (2) together with iodoaniline (4) and nitrobenzene (1) were obtained in the yields indicated in Scheme 1 (88% mass balance), which corresponds to a 62% selectivity for the formation of o iodoaniline (3). Under the same conditions, the ECH of o-iodonitrobenzene (2) gave aniline (90% yield) as the sole product. There was complete hydrogenolysis of the C-I bond (no selecti vity). Thus, in basic medium (pH 12.5), CCH method is much more selective than ECH. However, in weakly acidic medium (pH 3, pyridine.HCl buffer), it has been reported that ECH at a RCu cathode in methanol-water 95 5 (v/v) gave o-iodoaniline in a 97% yield (1, 3). 

The indole pharmacophore has attracted further attention in the work of Zhang et al. (see also below, Scheme 10), who used the route developed by Larock29 for the heteroannulation of internal alkynes with o-iodoanilines (Scheme 7).30 The cyclization proceeded well on the solid phase. In the case of unsymmetrical alkynes, the predominant species was the expected one with the more sterically demanding group in the 2-position. 

A common goal of library synthesis is to maximize diversity around a core, so the synthetic route described above was extended to accommodate a variety of substituted aryl groups. The modified route is shown in Scheme 11. The solid-phase starting material was Rink amide resin,36 which had been loaded with y-bromocrotonic acid (attempts to load with other suitable fragments, such as fumaraldehydic acid, or the pentafluorophenol-activated ester, failed). Substituted ort o-iodoanilines could then be used to alkylate... 

The synthetic utility of many of the substitution reactions described so far is limited because there are well-established thermal routes to the same products. However, a third group of photochemical nucleophilic substitutions involves aryl halides and nucleophiles based on sulfur, phosphorus or, of particular importance, carbon. Two examples are the reaction of bromobenzene with the anion of t-butyl methyl ketone 13.12), and the replacement of bromine by cyanomethyl in 2-bromopyridine (3.13). This type of reaction offers a clear advantage over lengthy thermal alternatives, and intramolecular versions have been used in the synthesis of indoles (e.g. 3.14) or benzofurans from o-iodoaniline or o-iodoanisole respectively. 

Electrostimulation of o-iodoaniline in the presence of enolate anions in liquid ammonia produced138 indoles in high yield, often better than the pho-tostimulated reactions [Eq. (67)]. 

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