Indole substituted , complexes

Methylthiophene is metallated in the 5-position whereas 3-methoxy-, 3-methylthio-, 3-carboxy- and 3-bromo-thiophenes are metallated in the 2-position (80TL5051). Lithiation of tricarbonyl(i7 -N-protected indole)chromium complexes occurs initially at C-2. If this position is trimethylsilylated, subsequent lithiation is at C-7 with minor amounts at C-4 (81CC1260). Tricarbonyl(Tj -l-triisopropylsilylindole)chromium(0) is selectively lithiated at C-4 by n-butyllithium-TMEDA. This offers an attractive intermediate for the preparation of 4-substituted indoles by reaction with electrophiles and deprotection by irradiation (82CC467). 

In contrast, Cozzi and Umani-Ronchi found the (salen)Cr-Cl complex 2 to be very effective for the desymmetrization of meso-slilbene oxide with use of substituted indoles as nucleophiles (Scheme 7.25) [49]. The reaction is high-yielding, highly enantioselective, and takes place exclusively at sp2-hybridized C3, independently of the indole substitution pattern at positions 1 and 2. The successful use of N-alkyl substrates (Scheme 7.25, entries 2 and 4) suggests that nucleophile activation does not occur in this reaction, in stark contrast with the highly enantioselective cooperative bimetallic mechanism of the (salen)Cr-Cl-catalyzed asymmetric azidolysis reaction (Scheme 7.5). However, no kinetic studies on this reaction were reported. 

Enantioselective additions of a,f)-unsaturated 2-acyl imidazoles, catalyzed by bis(oxazolinyl)pyridine-scandium(III)triflate complex, were used for the asymmetric synthesis of 3-substituted indoles. The complex 114 was one of the most promising catalysts. The choice of acetonitrile as the solvent and the use of 4 A molecular sieves were also found to be advantageous. The 2-acyl imidazole residue in the alkylation products of u,(i-unsaturated 2-acyl imidazoles could be transformed into synthetically useful amides, esters, carboxylic acid, ketones, and aldehydes (Scheme 32) [105]. Moreover, the catalyst 114 produced both the intramolecular indole alkylation and the 2-substituted indoles in good yield and enantioselectivity (Scheme 33) [106]. The complex... 

Indole is chlorinated with SOCI2 or aqueous NaOCl to give 3-chloroindole, and 3-bromoindole is formed with W-bromosuccinimide. Action of HNO3 indole causes oxidation of the pyrrole ring followed by polymerization. Indoles substituted in the 2-position react with HNO3 in acetic acid to give 3,6-dinitro compounds. Sulfonation of indole with pyridine-S03 complex leads to the formation of indole-3-sulfonic acid. 

Functionalization of indoles at C-4 can be achieved by the addition of nucleophiles to indole tricarbonylchromium complexes, followed by oxidative removal of the chromium. A recent example, from 1992, shows the formation of the 4-allylindole (164) following carbanion addition (Scheme 54) <92AJC99>. This technique has also been applied to formation of a 4-indolylbutenone, a key intermediate in the synthesis of clavicipitic acid <93TL5051>. 7-Substitution of the indole ring can... 

In 2007, Beller and co-workers described the first additive-free homogeneous N-alkylation of (hetero)aryl amines with aliphatic amines catalyzed by the Shvo complex with a low catalyst loading (1 mol%) (Eq. 73) [214]. The reactions of some challenging substrates, such as cyclic secondary amines, furan-, thiophene-, and indole-substituted amines, could also afford the corresponding products with good yields by this method. 

Guo and co-workers reported a highly enantioselective 1,3-dipolar cycloaddition of azomethine ylides with p-nucleobase-substituted acrylates as dipolarophiles using 1 mol% of a chiral Cu(I) complex, which provides the first rapid and divergent access to various enantioenriched azacyclic nucleoside analogues in high yields with excellent exo-selectivities and enantioselectivities (Scheme 8) [19]. In addition, other p-heteroarylacrylates such as pyrimidine-, benzimidazole-, imidazole-, benzotriazole-, and indole-substituted acrylates are also suitable... 

Substituted indoles can be obtained by the same general method starting with 3-acylpyrroles[2]. The precise methodology for construction of the substituent can be adapted as necessary for more complex structures. For example, enantioselective syntheses of both cis and traus-trikentin A and herbindoles A, B and C have been accomplished by using the annelation methodology[3]. 

Aromatization of indolines is important in completing synthetic sequences in which the directive effects of the indoline ring have been used to achieve selective carbocyclic substitution[l]. Several methods for aromatization have been developed and some of these are illustrated in Table 15.2. A range of reagents is represented. One type of procedure represents use of oxidants which are known to convert amines to imines. Aromatization then provides the indole. Such reagents must not subsequently oxidize the indole. Mereuric acetate (Entry 1) is known to oxidize other types of amines and presumably reacts by an oxidative deprotonation ot- to the complexed nitrogen. 

Nitration. Because nitration frequentiy generates nitrogen oxides which can participate in oxidative transformations, the nitration of indole itself is a complex reaction. In strongly acidic media, the nitration of 2-substituted indoles can proceed through the conjugate acid (8). Because the aromatic system is thereby transformed to an a2astyrene, the 5-position is the primary site of reaction. 

The reactivity sequence furan > tellurophene > selenophene > thiophene is thus the same for all three reactions and is in the reverse order of the aromaticities of the ring systems assessed by a number of different criteria. The relative rate for the trifluoroacetylation of pyrrole is 5.3 x lo . It is interesting to note that AT-methylpyrrole is approximately twice as reactive to trifluoroacetylation as pyrrole itself. The enhanced reactivity of pyrrole compared with the other monocyclic systems is also demonstrated by the relative rates of bromination of the 2-methoxycarbonyl derivatives, which gave the reactivity sequence pyrrole>furan > selenophene > thiophene, and by the rate data on the reaction of the iron tricarbonyl-complexed carbocation [C6H7Fe(CO)3] (35) with a further selection of heteroaromatic substrates (Scheme 5). The comparative rates of reaction from this substitution were 2-methylindole == AT-methylindole>indole > pyrrole > furan > thiophene (73CC540). 

The possibility of activating the indole nucleus to nucleophilic substitution has been realized by formation of chromium tricarbonyl complexes. For example, the complex from TV-methylindole (215) undergoes nucleophilic substitution with 2-lithio-l,3-dithiane to give a product (216) which can be transformed into l-methylindole-7-carbaldehyde (217) (78CC1076). 

The indol-3-yl-substituted indolo[2,3-()]carbazole 143 has been isolated as a product from the complex mixture generated by the decomposition of urorosein (144) (99CHE561). Interestingly, when subjected to alkylation conditions involving sodium hydride and dimethyl sulfate in THF, 143 was transformed into the N. -dimethyl derivative 145 in 36% yield (00MI2). 

Chlorogenic acid forms a 1 1 complex with caffeine, which can be crystallized from aqueous alcohol and yields very little free caffeine on extraction with chloroform. Other compounds with which caffeine will complex in this way include isoeugenol, coumarin, indole-acetic acid, and anthocyanidin. The basis for this selection was the requirement for a substituted aromatic ring and a conjugated double bond in forming such a complex. This kind of complex does modify the physiological effects of caffeine.14 Complex formation will also increase the apparent aqueous solubility of caffeine in the presence of alkali benzoates, cinnamates, citrates, and salicylates.9... 

Indoles, pyrroles, and carbazoles themselves are suitable substrates for palladium-catalyzed coupling with aryl halides. Initially, these reactions occurred readily with electron-poor aryl halides in the presence of palladium and DPPF, but reactions of unactivated aryl bromides were long, even at 120 °C. Complexes of sterically hindered alkylmonophosphines have been shown to be more active catalysts (Equation (25)). 8 102 103 In the presence of these more active catalysts, reactions of electron-poor or electron-rich aryl bromides and electron-poor or electron-neutral aryl chlorides occurred at 60-120 °C. Reactions catalyzed by complexes of most of the /-butylphosphines generated a mixture of 1- and 3-substituted indoles. In addition, 2- and 7-substituted indoles reacted with unhindered aryl halides at both the N1 and C3 positions. The 2-naphthyl di-t-butylphosphinobenzene ligand in Equation (25), however, generated a catalyst that formed predominantly the product from A-arylation in these cases. 

Organometallic complexes of copper, nickel, and palladium have been used in indole syntheses from arenes. Most of the reactions proceed under relatively mild conditions and in some cases give rise to formation of the less common 2-substituted compounds.68 Good yields of such 2-substituted derivatives are formed in reactions of o-iodoarylamines with cuprous acetylides in dimethylformamide (Scheme 41 ).69 The efficiency of this type of... 

The specific ortho functionalization of arylamines is obviously important in quinoline synthesis (cf. the rc-allyl procedure devised for the preparation of o-allylanilines used as indole and quinoline precursors).76 Recently acetanilides have been subjected to orthopalladation and the ensuing complexes converted into useful precursors of 2-substituted quinoline derivatives (Scheme 143).215... 

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