Indoles of 3-

Dimethylaminomethylindole (gramine). Cool 42 5 ml. of aqueous methylamine solution (5 2N ca. 25 per cent, w/v) contained in an 100 ml. flask in an ice bath, add 30 g. of cold acetic acid, followed by 17 -2 g. of cold, 37 per cent, aqueous formaldehyde solution. Pour the solution on to 23 -4 g. of indole use 10 ml. of water to rinse out the flask. Allow the mixture to warm up to room temperature, with occasional shaking as the indole dissolves. Keep the solution at 30-40° overnight and then pour it, with vigorous stirring, into a solution of 40 g. of potassium hydroxide in 300 ml. of water crystals separate. Cool in an ice bath for 2 hours, collect the crystalline solid by suction flltration, wash with three 50 ml. portions of cold water, and dry to constant weight at 50°. The yield of gramine is 34 g. this is quite suitable for conversion into 3-indoleacetic acid. The pure compound may be obtained by recrystaUisation from acetone-hexane m.p. 133-134°. 

Sundberg, R. J. 1970, 77ie Chemistry of Indoles, Academic Press New York London Svoboda, M. Zavada, J. Sicher, J. 1965, Coll. Czech. Chem. Commun. 30, 413 Swem, D. 1953, Org. Reaa. (N. Y.) 7, 378... 

The material in the succeeding chapters describes both the synthesis of the indole ring and means of substituent modification which are especially important in indole chemistry. The first seven chapters describe the preparation of indoles from benzenoid precursors. Chapter 8 describes preparation of indoles from pyrroles by annelation reactions. These syntheses can be categorized by using the concept of bond disconnection to specify the bond(s) formed in the synthesis. The categories are indicated by the number and identity of the bond(s) formed. This classification is given in Scheme 1.1. 

Chapters 9, 10 and 11 describe methods for substitution directly on the ring with successive attention to Nl, C2 and C3. Chapters 12 and 13 are devoted to substituent modification as C3. Chapter 12 is a general discussion of these methods, while Chapter 13 covers the important special cases of the synthesis of 2-aminoethyl (tryptaminc) and 2-aminopropanoic acid (tryptophan) side-chains. Chapter 14 deals with methods for effecting carbo cyclic substitution. Chapter 15 describes synthetically important oxidation and reduction reactions which are characteristic of indoles. Chapter 16 illustrates methods for elaboration of indoles via cycloaddition reactions. 

There are a number of other sources of information available about the synthesis of indoles. The most comprehensive entree to the older literature is through Volume 25, Parts I-IIl, of The Chemistry of Heterocyclic Compounds, which were published between 1972 and 1979[23]. Work to the early 1980s is reviewed in Comprehensive Heterocyclic Chemistry[24 and a second edition is forthcoming[25]. Other reviews emphasizing recent developments are also availablc[26-28]. 

A two-step synthesis of indoles from o-nitrobenzaldehydes proceeds by condensation with nitromcthanc followed by reductive cyclization. Like the Leim-gruber Batcho method, the principal application of the reaction is to indoles with only carbocyclic substituents. The forniation of the o,p-dinitrostyrenes is usually done under classical Henry condensation conditions but KF/18-crown-6 in propanol was found to be an advantageous reaction medium for acetoxy-substituted compounds[1]. The o,p-dinitrostyrenes can also be obtained by nitration of p-nitrostyrenes[2]. 

Esters of indole-3-carboxylic acid can be made in two steps starting with an o-bromoaniline and an acrylate cstcr[2]. 

The main example of a category I indole synthesis is the Hemetsberger procedure for preparation of indole-2-carboxylate esters from ot-azidocinna-mates[l]. The procedure involves condensation of an aromatic aldehyde with an azidoacetate ester, followed by thermolysis of the resulting a-azidocinna-mate. The conditions used for the base-catalysed condensation are critical since the azidoacetate enolate can decompose by elimination of nitrogen. Conditions developed by Moody usually give good yields[2]. This involves slow addition of the aldehyde and 3-5 equiv. of the azide to a cold solution of sodium ethoxide. While the thermolysis might be viewed as a nitrene insertion reaction, it has been demonstrated that azirine intermediates can be isolated at intermediate temperatures[3]. 

Preparation of indole-2-carboxylate esters by the Hemetsberger method... 

A solution of trifluoroacetic acid in toluene was found to be advantageous for cydization of pyruvate hydrazoncs having nitro substituents[4]. p-Toluene-sulfonic acid or Amberlyst-15 in toluene has also been found to give excellent results in preparation of indole-2-carboxylale esters from pyruvate hydra-zoiies[5,6J. Acidic zeolite catalysts have been used with xylene as a solvent to convert phenylhydraziiies and ketones to indoles both in one-flask procedures and in a flow-through reactor[7]. 

Carbocations stabilized by functional groups can also effect 3-alkylalion of indoles. From a synthetic point of view the most important are jV.jV-dialkyl-methyleneiminium ions which can be generated under Mannich conditions from formaldehyde and secondary amines[13]. The products, 3-(A/,A-dialkyl-aminornethyl)indoles, are useful synthetic intermediates (see Chapter 12). 

Epoxides and aziridines are also capable of electrophilic subsitution of indoles. Indolylmagncsium bromide and cyclohexene oxide react to give 3-(lrans-2-hydroxycyclohexyl)indole[14]. Reaction of indoles with epoxides also occurs in the presence of Lewis acids. For example, indole reacts with methyl 2S,3R-epoxybutanoate at C3 with inversion of configuration[15]. 

Lewis acids such as zinc triflate[16] and BF3[17] have been used to effect the reaction of indole with jV-proiected aziridine-2-carboxylate esters. These alkylations by aziridines constitute a potential method for the enantioselective introduction of tryptophan side-chains in a single step. (See Chapter 13 for other methods of synthesis of tryptophans.)... 

Alkylation can also be accomplished with electrophilic alkenes. There is a dichotomy between basic and acidic conditions. Under basic conditions, where the indole anion is the reactive nucleophile, A-alkylation occurs. Under acidic conditions C-alkylation is observed. The reaction of indole with 4-vinylpyri-dine is an interesting illustration. Good yields of the 3-alkylation product are obtained in refluxing acetic acid[18] whereas if the reaction is done in ethanol containing sodium ethoxide 1-alkylation occurs[19]. Table 11.2 gives some examples of 3-alkylation using electrophilic alkenes. 

Section C of Table 11,5 gives some examples of Friedel-Crafts and Vilsmeier-Haack acylations of indoles. 

Phenylmagnesium bromide (2.8 mol) was prepared in anhydrous ether (21) from bromobenzene (440 g, 2.9 mol) and magnesium turnings (68.0 g 2.8 g-atom). To this solution was added dropwise a solution of indole (328 g, 2.8 mol) in benzene (8(X)ml). The resulting solution was stirred for 10 min and then a solution of cyclopentanoyl chloride (322 g, 2.4 mol) in benzene (800 ml) was added dropwise. The solution was stirred for 1 h and then water (11) was added carefully. The precipitate which formed was collected by filtration and dried to give 169 g of crude product. Additional product (97 g) was obtained by evaporation of the organic layer of the filtrate. The combined products were recrystallized from toluene to give 250 g (49% yield) of pure product. 

Sulfenylation of indoles can be carried out with sulfenyl halides[7], disulfides[7-9] or with A -methylthiomorpholine[10]. With disulfides the indoles are converted to lithium[8] or zinc[9] salts prior to sulfenylation. Thiophenols and iodine convert indoles to 3-(arylthio)indoles[l 1]. 

Tryptophans can also be prepared by reduction of a,(3-dehydrotryptophans. These can be obtained by a classical azlactone type synthesis from derivatives of indole-3-carboxaldehyde. These reactions usually rquire an iV-EW substituent and the yields are modest[15]. 

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