Indole Vilsmeier reaction

Convert indole to indolyl-3-methyl-ketone (I) by treating indolyl-Mg-Br (preparation already described) with acetyl-Cl, by treating indole in POCl3 with dimethylacetamide (Vilsmeier reaction), or by reacting indole with diketene (ACS 22,1064(1968)). 15.9 g (1) in 50 ml methanol cool, stir and add dropwise 16 g Br2. Reflux 1 Vi hours on water bath cool, filter, wash with ether and recrystallize-methanol to get 18 g indolyl-3-Br-methyl-ketone (II). Dissolve 11.9 g (II) in 60 ml warm isopropanol and add 11 g 3 8% aqueous DMA (or equimoiar amount other amine) reflux one hour on water bath. Filter (recrystallize-ethanol) to get 8.5 g indolyl-3-dimethylamino-methyl ketone (III). Add 4.6 g (0.02 M) (III) in 30 ml tetrahydrofuran to 2.3 g lithium aluminum hydride in 50 ml tetrahydrofuran, stir one-half hour at room temperature and reflux two hours. Add a little water dropwise and extract the precipitate with acetone. Dry, evaporate in vacuum the combined organic phases to get an oil which will precipitate with ether-petroleum ether to give DMT. (Ill) should be tested for psychedelic activity. Dialkyltryptamines BCSJ 11,221 (1936), BSC 2291 (1966)... 

Vilsmeier reaction of 2-oxindole (830) afforded 2-chloroindole-3-carbaldehyde (891). Suzuki cross-coupling of 891 with furan-3-boronic acid (1124), followed by protection of the indole nitrogen with benzyloxymethyl (BOM) chloride, led to... 

When DMF and phosphorus oxychloride are reacted together in the Vilsmeier reaction, the A,A-dimethylamino(chloro)methyleniminium cation is generated, and this reacts with indole at 5 °C to give 3-(A,A-dimethylaminomethylene)indolenine (see Section 6.1.2). When hydrolysed by treatment with dilute sodium hydroxide, this gives an excellent yield of 3-formylindole (Scheme 7.5). 

The mechanism of the Mannich reaction is similar to that of the Vilsmeier reaction as the electrophile is also a methyleniminium cation, formed this time from a condensation of dimethylamine and formaldehyde in acetic acid solution (Scheme 7.7a). This reacts with indole to yield 3-(A, 7V-dimethylaminomethyl)indole (although not shown, it is possible that initial attack occurs at N-1 and rearrangement of the side chain to C-3 takes place in a follow-up step) (Scheme 7.7b). Scheme 7.7... 

These compounds are less common than indole (benzo[ ]pyrrole). In the case of benzo[i>]furan the aromaticity of the heterocycle is weaker than in indole, and this ring is easily cleaved by reduction or oxidation. Electrophilic reagents tend to react with benzo[Z ]furan at C-2 in preference to C-3 (Scheme 7.21), reflecting the reduced ability of the heteroatom to stabilize the intermediate for 3-substitution. Attack in the heterocycle is often accompanied by substitution in the benzenoid ring. Nitration with nitric acid in acetic acid gives mainly 2-nitrobenzo[Z ]furan, plus the 4-, 6- and 7-isomers. When the reagent is in benzene maintained at 10 °C, both 3- and 2-nitro[ ]furans are formed in the ratio 4 1. Under Vilsmeier reaction conditions (see Section 6.1.2), benzo[Z ]furan gives 2-formylbenzo[6]furan in ca. 40% yield. 

Similarly, using the Vilsmeier reaction an aldehyde group can he brought in at C-3 of indole. 

The Vilsmeier-Haack reaction (herein, Vilsmeier reaction ) provides an effective method for the formylation of aromatic systems. The combination of phosphoryl chloride with V-methylaniline or dimethylformamide generates an iminium phosphorus derivative or chloro-iminium cation that is the active electrophile in an electrophilic substitution reaction. The resulting substitution product is an iminium salt 1, which is hydrolyzed on workup with alkali to give the carbaldehyde product 2 (Scheme l).1,2 The method is particularly useful with activated arenes or electron-rich heterocycles, such as pyrroles, furans, thiophenes, and indoles. We had a special interest in the preparation of indole-7-carbal-dehydes, namely, their properties as isosteres of salicylaldehyde. Thus, we became involved in a wide-ranging investigation of 4,6-dimethoxy-... 

The Vilsmeier reaction proceeds extremely well with indoles giving aldehydes such as 7.28. 

The Vilsmeier reaction is a very efficient method for the preparation of 3-formyl-indoles/° and for other 3-acyl-indoles using tertiary amides of other acids in place of dimethylformamide. Even indoles carrying an electron-withdrawing group at the 2-position, for example ethyl indole-2-carboxylate, undergo smooth Vilsmeier 3-formylation. ... 

Reactions with electrophilic reagents take place with substitution at C-3 or by addition at the pyridine nitrogen. All the aza-indoles are much more stable to acid than indole (cf. 20.1.1.9), no doubt due to the diversion of protonation onto the pyridine nitrogen, but the reactivity towards other electrophiles at C-3 is only slightly lower than that of indoles. Bromination and nitration occur cleanly in all four parent systems and are more controllable than in the case of indole. Maniuch and Vilsmeier reactions can be carried out in some cases, but when the latter fails, 3-aldehydes can be prepared by reaction with hexamine, possibly via the anion of the azaindole. Alkylation under neutral conditions results in quatemisation on the pyridine nitrogen and reaction with sodium salts allows A-1-alkylation. Acylation under mild conditions also occurs at N-1. The scheme below summarises these reactions for the most widely studied system - 7-azaindole. Acylation at C-3 in all four systems can be carried out at room temperature in the presence of excess aluminium chloride. ... 

Conducted in an intramolecular sense, both Mannich and Vilsmeier reactions have been much used for the construction of tetrahydro-/3-carbolines (dihydro-/ -carbolines), such as are found in many indole alkaloids (/ -carboline is the widely-used, trivial name for the pyrido[3,4-Z>]indole). 

The synthesis of Trp-P-2[2] started with an intermediate, indole-2-acetonitrile[9](24), prepared from commercially available indole-2-carboxylic acid[87. Vilsmeier reaction(25) of [9], with dimethylacetamideand phosphoryl chloride, gave 3-acetylindole-2-acetonitrile[10]. Cyclization of [10] on treatment with methanolic ammonia and aromatization involving a hydrogen transfer of the a-methylene group yielded the desired 3-amino-l-methyl-5H-pyrido (4,3b)indole[2] m/e 197(M+) vmax(KBr) 1635,1605 cm l 6 (CD3OD) 2.3(3H,s), 5.92(lH,s), 6.53-7.00(3H,m), 7.35(lH,d). 

Hyellazole (3a) has been synthesized according to Scheme 7 2-63. regioselective lithiation of 1-benzenesulphonylindole in the 2-position, followed by addition of propiophenone and alkaline hydrolysis, yielded the 2-vinylindole 17. A Vilsmeier reaction, followed by a Wittig reaction with methoxymethylenetriphenyl-phosphorane, gave the 2,3-divinylic indole 18. Finally, heating in decaline in the presence of Pd-C cyclized 18 to produce hyellazole (3a). Chlorohyellazole (3b) was similarly obtained. 

Isatins are indole derivatives with broad use in synthetic dye production and are intermediates in the synthesis of other heterocyclic molecules/ They also possess a variety of biological activities/ Aksenov et al. reported a one-pot synthesis of isatins using ethyl nitroacetate with substituted benzenes such as anisole (159) in polyphosphoric acid fScheme 5.38)/ The process for isatin formation likely includes a hybrid between the Nef and Vilsmeier reactions of anisole 159 and nitro ester 160 to form the oxime intermediate 161, which then undergoes a Beckmann rearrangement to give the anilide 162. Subsequent intramolecular acylation yields isatin 163. 

Indolin-2-ones can participate in Vilsmeier reactions with reactive aromatics under the agency of Tf20. In the reaction with indoles and benzofurans, Tf20 was found to be the reagent of choice no reaction took place when phosphorous oxychloride... 

Vilsmeier-Haack conditions have been used most frequently for formylation but are also applicable to longer acyl chains[3]. Reactions with lactams generate 3-(iminyl)indoles which can be hydrolysed to generate co-aminoacyl groups as in equation 11.6 [4]. 

Vilsmeier-Haack formylation, 4, 222 Indole, dimethyl- C NMR, 4, 172 Indole, 1,2-dimethyl-bis-allylation, 4, 357 Indole, 1,3-dimethyl-nitration, 4, 211 reactions... 

Vilsmeier-Haack and Friedel-Crafts reactions, bromination, debromination, debenzylation in indole series and their synthetic application 99YZ35. 

During synthetic studies toward pynrolo-fiised indoles, the polymeric species 218 has been suggested as aproduct from the diformylation of 219 under Vilsmeier-Amold-Haack conditions, followed by heating with 35% aqueous sulfuric acid (Scheme 33) (9171,5035). With the deeper knowledge of the reactions of 3-formylIndoles now available (99CHE561), this assignment should be reconsidered. 

With respect to aromatic substrates, the Vilsmeier formylation reaction works well with electron-rich derivatives like phenols, aromatic amines and aromatic heterocycles like furans, pyrroles and indoles. However various alkenes are also formylated under Vilsmeier conditions. For example the substituted hexatriene 6 is converted to the terminal hexatrienyl aldehyde 7 in 70% yield ... 

In miscellaneous oxidative processes of indoles, two methods for the preparation of 3-hydroxyindoles have been reported. The first approach involves initial Vilsmeier-Haack reaction of indole-2-carboxylates 176 to afford the corresponding 3-formyl analogs 177. Activation of the aldehyde with p-toluenesulfonic acid (PTSA) and Baeyer-Villiger oxidation with m-chloroperoxybenzoic acid (wi-CPBA) then affords high yields of the 3-hydroxy compounds 178 <00TL8217>... 

A multi-stage synthesis of azocino[4,5,6-cd]indoles has been suggested (03M13519). From 4-bromoindole (84) with the help of successive transformations (among them the Vilsmeier-Haack reaction, Henry nitroaldole condensation, lithium aluminum hydride reduction and insertion of an allyl fragment), indole 85 has been produced in 18% yield. The cyclization of the latter on palladium... 

Recently, Moody et al. reported a biomimetic synthesis of calothrixin B (378) by oxidation of Hibino s 6-formylindole[2,3-fl]carbazole 1555 (870). The key intermediate 6-formyl-indole[2,3-fl]carbazole was readily obtained in six steps from indigo (1458). Using Somei s procedure, indigo (1458) was transformed to the cis-chlorohydrin 1461 in three steps and 50% overall yield (see Scheme 5.247). The reduction of the chlorohydiin 1461 gave 5-hydroxy-indolo[2,3-fl]carbazole 1564, and subsequent Vilsmeier formylation delivered the desired 6-formyl-indole[2,3-fl]carba-zole 1565 in 45% yield. Reaction of hydroxy-indolocarbazole 1565 with an excess of chloromethyl methyl ether (MOMCI) afforded the tiis-MOM-protected compound 1555. Following Hibino s approach, the tris-MOM-protected indolocarbazole 1555... 

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