Aromatic substitution ring closure with

Tetrahydroharman, m.p. 179-80°, has been prepared by a number of workers by a modification of this reaction, viz., by the interaction of tryptamine (3-)5-aminoethylindole) with acetaldehyde or paraldehyde and Hahn et al. have obtained a series of derivatives of tetrahydronorharman by the use of other aldehydes and a-ketonic acids under biological conditions of pH and temperature, while Asahina and Osada, by the action of aromatic acid chlorides on the same amine, have prepared a series of amides from which the corresponding substituted dihydronorharmans have been made by effecting ring closure with phosphorus pentoxide in xylene solution. 

Condensation ofDianhydrides with Diamines. The preparation of polyetherknides by the reaction of a diamine with a dianhydride has advantages over nitro-displacement polymerization sodium nitrite is not a by-product and thus does not have to be removed from the polymer, and a dipolar aprotic solvent is not required, which makes solvent-free melt polymerization a possibiUty. Aromatic dianhydride monomers (8) can be prepared from A/-substituted rutrophthalimides by a three-step sequence that utilizes the nitro-displacement reaction in the first step, followed by hydrolysis and then ring closure. For the 4-nitro compounds, the procedure is as follows. 

Polyfluorinated a-diketones react with 1,2-diainino compounds, such as ortlio-phenylenediamine, to give 2,3-substituted quinoxalmes [103] Furthermore, the carboxyl function of trifluoropyruvates offers an additional electrophilic center. Cyclic products are obtained with binucleophiles [13, 104] With aliphatic or aromatic 1,2-diamines, six-memhered heterocycles are formed Anilines and phenols undergo C-alkylation with trifluoropyruvates in the ortho position followed by ring closure to form y-lactams and y-lactones [11, 13, 52, 53, 54] (equation 23). 

Amides, prepared by condensation of tryptamine or substituted tryptamines with a large number of aliphatic, homocyclic, aromatic,and heterocyclic acids, have been used in the reaction. In few cases only did ring closure fail. ... 

Alkenyl Fischer carbene complexes can serve as three-carbon components in the [6 + 3]-reactions of vinylchro-mium carbenes and fulvenes (Equations (23)—(25)), providing rapid access to indanone and indene structures.132 This reaction tolerates substitution of the fulvene, but the carbene complex requires extended conjugation to a carbonyl or aromatic ring. This reaction is proposed to be initiated by 1,2-addition of the electron-rich fulvene to the chromium carbene followed by a 1,2-shift of the chromium with simultaneous ring closure. Reductive elimination of the chromium metal and elimination/isomerization gives the products (Scheme 41). 

Abstract 2,4-Disubstituted-3,4-dihydro-2/f-naphth[2,l-e][l,3]oxazines were prepared through the ring-closure reactions of the starting aminonaphthols with substituted aromatic and hetaryl aldehydes. 

The selective oxidation of the activated aromatic ring, substituted with electron-donating hydroxy or methoxy groups, can be perfomed at relatively low electrode potential (Ep = 0.3-1.2 V vs SCE) and ring closure is the result of the intramolecular nucleophilic attack of an amino group on the oxidized aromatic ring. 

A common feature of any cyclization reaction is that a new intramolecular C—C bond is produced that would not have been formed in the absence of the catalyst. Those reactions in which one ring closure step is sufficient to explain the formation of a given cyclic product will be called simple cyclization processes, although their mechanism is, as a rule, complex. We shall distinguish those cases in which any additional skeletal rearrangement step(s) is (are) required to explain the process. Some specific varieties of hydrocarbon ring closure processes are not included. A recent excellent review deals with the formation of a second ring in an alkyl-substituted aromatic compound (12). Dehydrocyclodimerization reactions have also to be omitted—all the more since it is doubtful whether a metallic function itself is able to catalyze this process (13). 

A recent development in the synthesis of 3//-3-benzazepin-2-ones has been the photocyc-lization of A-(chloroacetyl)phenethylamines (Scheme 25). Ring closure is by homolysis of the alkyl halide followed by intramolecular coupling of the alkyl radical with an aromatic radical cation. Yields are good, especially with a stabilizing electron-donating group (MeO, NMe2) at the position meta to the ethylamino function (i.e. ortho or para to the site of cyclization). Isomeric benzazepinones are normally obtained (Scheme 25) with meta-substituted phenethylamines (80H(14)ll). 

The reactions in Methods A, B and C, which all start from pyrylium salts are analogous to the well-known conversions of 2.4.6-substituted pyrylium salts 27 with ammonia, primary amines, hydrogen sulfide or the anions of CH activated compounds to the corresponding heterocyclic or isocyclic aromatic systems The first step involves addition of the basic phosphine at C-2 (or C-6) to form 2S. Ring-opening, ring-closure and elimination of water are likely steps in the formation of the product 2. 

The fully aromatic diquaternary system 81 is prepared by acid ring closure of the salt (79) obtained by quaternization of 1,10-phen-anthroline with bromoacetaldehyde followed by dehydration of the resulting hydroxy diquaternary salt (80) with thionyl chloride.310,311 The salt 81 is unstable in aqueous solution above a pH of about 5.0. In the pH range 3.3-5.0 it is reduced by a one-electron transfer to the corresponding radical cation at a potential (E0) of —0.12 volt.311 Its reduction in dimethylformamide solution has also been studied.15,307 Substituted derivatives of 81 have been prepared.312... 

Secondary aliphatic amines reacted readily with mercaptoaldimines (279), which could be prepared readily by the action of Na/NH3 on the aldehyde diacetals (278). The resulting N,N- dialkyl derivatives (280) were alkylated on sulfur by a-halocarbonyl compounds such as bromoacetic acid the resulting products (281) underwent spontaneous ring closure and aromatization via loss of the secondary amine to yield the acids (282 Scheme 97). Decarboxylation of the acids (282) furnished the substituted thieno[2,3-6 ]thiophenes (283). The use of other a-halocarbonyl compounds, such as bromoacetone or phenacyl bromide for the alkylation, led to the formation of the 2-acetyl or 2-benzoyl derivatives, (284) and (285) respectively (76AHC(19)123). 

Acceptor-substituted haloarenes have been successfully used to O-arylate phenols by aromatic nucleophilic substitution (Table 7.14). The most common arylating agents are 2-fluoro-l-nitroarenes, 2-halopyridines, 2-halopyrimidines, and 2-halotriazines. When sufficiently reactive haloarenes are used, the reaction proceeds smoothly with either the arylating agent or the phenol linked to the support. The thallium(III) nitrate catalyzed arylation of phenols with aryl iodides has been used for macrocycli-zations on solid phase [184], Burgess and co-workers have developed a solid-phase synthesis of 3-turri mimetics based on ring-closure by aromatic nucleophilic substitution (Entry 4, Table 7.14 see also Table 10.5). Phenols, alkylamines, and thiols have been successfully used as nucleophiles for this type of macrocyclization [185],... 

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