Ring closure with aryl halides

Although sodium sulphide reacts readily with haloalkanes [2] and activated aryl halides (see Chapter 2) [e.g. 3-5] in the presence of a quaternary ammonium catalyst to form symmetrical thioethers (Table 4.1), a major side reaction results in the formation of disulphides owing to the oxidation of the intermediate thiols under the basic conditions. Consequently, little use has been made of this procedure for the synthesis of thioethers [3, 6], but the corresponding reaction of the a,(0-dihaloalkanes to yield cyclic thioethers has proved to be a valuable procedure for the synthesis of thietanes [7] (Table 4.2). The ring closure with the secondary dihaloalkanes is considerably more difficult to effect than is the reaction of the primary dihaloalkanes. 1,3-Dihydrobenzo[c]thiophene (89%) is produced in the reaction of 1,2-bis(bromomethyl)benzene with sodium sulphide (Scheme 4.1) [8]. The direct... 

NaNHR, or NaNR2. Lithium dialkylamides also react with aryl halides to give the A-arylamine. With these reagents, the benzyne mechanism generally operates, so cine substitution is often found. The reaction of an amine, an aryl halide, and potassium tert-butoxide generates the A -aryl amine. A -Arylation was accomplished with butyllithium and a secondary amine using Ni/C-diphenylpho-sphinoferrocene (dppf). Ring closure has been effected by this type of reaction, as in the conversion of 16 to the tetrahydroquinoline. 

Unactivated aryl halides can be converted to amines by the use of NaNH2, NaNHR, or NaNR2. With these reagents, the benzyne mechanism generally operates, so cine substitution is often found. Ring closure has been effected by this type of reaction,for example. 

A concerted elimination-cyclization mechansim, involving a sulfenyl halide in a 1,3-butadiene-1-thio system, is the most probable mechanism for the formation of benzo[6 Jthiophenes from cinnamic acids or 4-aryl-2-butanones by treatment with thionyl chloride. The reactions shown in Scheme 5 have been carefully worked out, and the intermediates isolated (75JOC3037). The unique aspect of this synthesis is the reduction of the sulfinyl chloride (a) by thionyl chloride to form the sulfenyl chloride (b). The intermediate (b) was isolated and converted in pyridine to the 3-chlorobenzo[6]thiophene-2-carbonyl chloride in 36% yield (73TL125). The reaction is probably initiated by a sulfenyl ion attack on the aromatic ring, since it is promoted by electron-releasing groups para to the site of ring closure. For example, when X in (36) was N02, a 23% yield of (37), a mixture of 5-and 7-nitro derivatives, was obtained, but when X in (36) was OMe, a 54% yield of (37) was obtained, contaminated with some 3,4-dichloro-5-methoxybenzo[6]thiophene-2-carboxylic acid. 

Ring closure reactions taking place by intramolecular addition of an aromatic radical to a double bond have been widely studied on both their regio- and stereochemical aspects [93]. Aryl halides and diazonium salts substituted at ortho- position with a 0-allyl or TV-allyl chain were used for the preparation of 2,3-dihydrobenzofuranes and 2,3-dihydro-1/7-indoles under different reaction conditions. The reaction pattern involves the generation of an aryl radical 20, which reacts with the double bond in a 5-exo trig fashion to afford the exocyclic radical 21, plausible of reduction by a hydrogen donor to obtain the reduced-cyclized product 22 (Sch. 23) [93d,94]. 

Just as in aryl halides, the halogen can be replaced by hydrogen and by a metal, or be involved in transition metal-catalyzed processes (covered in Section 3.2.3.11.2). Three of the mechanisms of such nucleophilic substitutions are familiar from benzene chemistry via arynes, SrnI processes, and Pd(0)-catalyzed sequences. However, of the two further mechanisms of nucleophilic replacement, the ANRORC (Addition of Micleophile, Ring Opening, Ring Closure) is unique to heterocycles, and Sae reactions occur only with strongly activated benzenoid systems. 

Ring closure onto an aryl ring is a frequently reported strategy for formation of a benzazepine with examples including a Heck reaction for the cyclization of an allyl amine with an aryl halide to form the 3-benzazepine core in the... 

In a narrower sense, this review covers intramolecular Mizoroki-Heck [1] reactions forming carbocycles [2] that is, the palladium-catalyzed intramolecular coupling of vinyl/aryl (pseudo-)halides with an alkene tethered by a hydrocarbon chain. Ring closures furnishing heterocycles are covered in Chapter 6 also beyond the scope of this chapter are the domino/cascade or tandem (Chapter 8) and asymmetric processes (Chapters 12 and 16) dealing with formation of a carbocycle. 

To overcome the ring closure of intermediate 10 giving rise to by-product 8 that was particularly encountered with secondary alkyl halides. Tautens and coworkers [22] developed conditions that favor the oxidative addition of alkyl hahdes. The methodology was widely applied to the intramolecular (Scheme 19.12) and intermolecular ortho alkylation of aromatic C-H bonds with secondary alkyl iodides and bromides [23]. Depending on the terminating reactions employed (the Heck reaction, direct arylation of heterocycles, and the Buchwald-Hartwig amination), a variety of valuable heterocydes were efficiently prepared. It should be pointed out that the reaction of enantioenriched substrates occurred with... 

Palladium-catalyzed reaction of bis(o-trifluoroacetamidophenyl) acetylene 685 with various aryl and vinyl halides and triflates led to the formation of indolo[l,2-c] quinazolines 686 (Scheme 143) [406]. If the reaction was performed in presence of CO, the corresponding acyl derivatives 687 were obtained [407], In both cases, the indole heterocyclic system was formed first the subsequent pyrimidine ring closure resulted in construction of the tetracyclic ring system. 

Several papers report on the nucleophilic reactivity of dithiocarbamate ions towards alkyl halides, 1,2-dibromoalkyl compounds, alkyl and aryl chloroformates, chloroacetic acid, chloroacetates, 3-halo-genophthalides, sulphenyl chlorides, sultones, and trialkylam-monium compounds. Examples of a similar reactivity of dithiocarbazate anions have also appeared. " A series of papers deal with addition or addition-elimination reactions of dithiocarbamate - or dithiocarbazate anions with w-nitrostyrene, 2-thioxo-, 2-oxo-, and 2-imino-5-methoxycarbonylmethylidene-4-thiazolidones, dimethyl acetylenedicar-boxylate, and NN -dialkyl phenylpropiolamidines. S-Monoalkylated N-cyanodithioimidocarbonates (492) underwent oxidative ring-closure to give 3-halogeno-l,2,4-thiadiazole sulphides (493) on treatment with halogenating agents. ... 

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