Cyclization bromo

Isomerized bromo derivatives of MBH adducts of isatin have been utilized to synthesize 3-spirocycloalkylindolones via reductive cyclization. Bromo derivative 4 as a mixture of ( )- and (Z)-isomers prepared from MBH adduct upon treatment with HBr embedded on silica gel under microwave irradiation has been subjected to reduction with NaBH4 at room temperature for 0.5 h (Scheme 4.2). Excellent yields of 3-spirocycloalkylindolones 5 were obtained, but with poor diastereoselectivities. 

RCM was used as a key step in the total synthesis of (+)-puraquinonic acid (86), a fungal metaboHte that induces differentiation in HL-60 cells [16]. Starting from aromatic aldehyde 87, the RCM precursor 88 was prepared in a few steps. Following RCM leading to 89 (88%), the newly formed trisubstituted alkene was involved in a radical cyclization. Bromo acetal 90 was treated with BusSnH and AIBN thus triggering a stereoselective 5-exo trig cyclization reaction. Further steps led to the natural product 86 (Scheme 1.13). 

With the catalysis of strong Lewis acids, such as tin(IV) chloride, dipyrromethenes may aiso be alkylated. A very successful porphyrin synthesis involves 5-bromo-S -bromomethyl and 5 -unsubstituted 5-methyl-dipyrromethenes. In the first alkylation step a tetrapyrrolic intermediate is formed which cyclizes to produce the porphyrin in DMSO in the presence of pyridine. This reaction sequence is useful for the synthesis of completely unsymmetrical porphyrins (K.M. Smith, 1975). 

Rudisill and Stille developed a two-step procedure in which 2-bromo-or 2-trifluoromethanesulfonyloxyacetanilides were coupled with tri-n-butyl-stannylacetylenes in the presence of Pd(PPh3)4.[l], Cyclization was then effected with PdCl2(CH3CN)2. The conditions are compatible with a variety of carbocyclic substituents so the procedure can provide 2-substituted indoles with carbocyclic substituents. The reported yield ranges from 40% to 97% for the coupling and from 40% to 82% for cyclization. 

An important reaction parameter is the choice of the base and NajCO or NaOAc have been shown to be preferable to EtjN in some systems[2]. The inclusion of NH4CI has also been found to speed reaction[2]. An optimization of the cyclization of A -allyl-2-benzyloxy-6-bromo-4-nitroaniline which achieved a 96% yield found EtjN to be the preferred base[3]. The use of acetyl or inethanesulfonyl as N-protecting groups is sometimes advantageous (see Entries 4 and 5, Table 4.1). 

A -(2 2-Diethoxyethyl)anilines are potential precursors of 2,3-unsubstituted indoles. A fair yield of 1-methylindole was obtained by cyclization of N-inethyl-M-(2,2-diethoxyethyl)aniline with BFj, but the procedure failed for indole itself[2], Nordlander and co-workers alkylated anilines with bromo-acetaldehyde diethyl acetal and then converted the products to N-trifliioro-acetyl derivatives[3]. These could be cyclized to l-(trifluoroacetyl)indoles in a mixture of trifluoroacetic acid and trifluoroacetic anhydride. Sundberg and... 

Transition-Metal Catalyzed Cyclizations. o-Halogenated anilines and anilides can serve as indole precursors in a group of reactions which are typically cataly2ed by transition metals. Several catalysts have been developed which convert o-haloanilines or anilides to indoles by reaction with acetylenes. An early procedure involved coupling to a copper acetyUde with o-iodoaniline. A more versatile procedure involves palladium catalysis of the reaction of an o-bromo- or o-trifluoromethylsulfonyloxyanihde with a triaLkylstaimylalkyne. The reaction is conducted in two stages, first with a Pd(0) and then a Pd(II) catalyst (29). 

This class was first reported in 1924 and was formed 62HC(17)l) by cyclization of a-bromo-/3-aryl-y-nitroketones. The direct synthesis by oxygenation of 2-isoxazolines has not been reported. To date only 3-substituted derivatives have been prepared. Aryl-nitromethanes react with nitrostilbene to form isoxazoline A-oxide by a nitrile ion displacement (Scheme 138) <62HC(17)1, 68TL3375). 

Acylazetidines were first synthesized by cyclization of 2-acyl substituted 3-bromo-propylamines with base (69JOC310). 

Cyclization of 3-bromo-2-bromomethylpropionamides CO insertion into 2-bromo-3-aminopropenes... 

A variety of conditions has been used to prepare oxiranes from trans-hxomo-hydrins. In general, bromohydrins are heated in a solution of 5-10% methanolic potassium hydroxide for 30 min to 8 hr. Longer reflux times are required for bromohydrins which are not anti-coplanar, e.g., diequatorial bromohydrins. A 5 % solution of potassium acetate in boiling ethanol can be used to cyclize steroidal bromohydrins containing base sensitive groups. The use of 1.1 equivalents of sodium methoxide per equivalent of steroid in methanol solution is especially recommended for 9a-bromo-l lj5-hydroxy steroids. 

Cyclization of 2-bromo-2-perfluoroalkylethyl acetate under PTC conditions provides perfluoroalkyl oxiranes [fO] (equation 9)... 

Benzylamine adds smoothly to 3,3,3-tnfluoro-2-bromopropene. The bromo-aUcy lamine thus formed cyclizes to 1 -benzyl-2-trifluoromethy lazindine [ 108] (equation 94). 

Intramolecular nucleophilic displacement of the bromo group by an azine-nitrogen occurs in the cyclization of A-2-quinaldyl-2-bromo-pyridinium bromide (248) to give the naphthoimidazopyridinium ring system. The reaction of 2-bromopyridine and pyridine 1-oxide yields l-(2-pyridoxy)pyridinium bromide (249) which readily undergoes an intramolecular nucleophilic substitution in which departure of hydrogen as a proton presumably facilitates the formation of 250 by loss of the JV-oxypyridyl moiety. 

Dihydrothiazoloquinoline is a key intermediate in the synthesis of natural sulfur-containing pyridoacridine alkaloids—kuanoniamines and derdercitins, where the starting dienone is converted after a multistep reaction sequence to an a-bromo-ketone, which in turn was cyclized with thiourea to the desired dihydrothiazoloquinoline, photochemically convertible to the final alkaloid derivatives 39 (Scheme 21) (92JA10081, 95TL4709, 95JA12460). 

The intramolecular cyclization of 2-alkynylaryldiazonium salts (Richter reaction) leads not only to 4-hydroxy- but also to 4-bromo- and 4-chlorocinnolines. The behavior of alkynylpyrazolediazonium chlorides differs from that of their benzene analogs. The Richter reaction of the series of alkynylaminopyrazoles gives only 4-halo derivatives of l//-pyrazolo[3,4-c]pyridazines and l//-pyrazolo[4,3-c] pyridazines, and mainly hydroxy derivatives of 2//-pyrazolo[3,4-c]pyridazines. 

Bromination of the diphenyl indole derivative 316 with bromine in DMF or trimethylammonium bromide afforded the 7-bromo derivative 317. Reaction with allyl bromide or its derivatives gave A-allyl derivatives 318 that upon cyclization with palladium acetate gave 7,9-dimethoxy-l,2-diphenylpyrrolo[3,2,l-// ]quinoline derivatives 319 (92T7601) (Scheme 57). 

Cyclohexene 6 undergoes cyclization with hydrogen bromide in diethyl ether at 0 C to give l-bromo-6,7,8,9-tetrahydro-477-2-benzazepin-3-amine hydrobromide (7), rather than the alternative isomer, 3-broino-7,8,9,9a-tetrahydro-6//-2-bcnzazcpin-l-amine (8). 

Benzene- 1,2-diacetonitriles e.g. 19, in the presence of hydrogen bromide in acetic acid, or in diethyl ether, cyclize to 4-bromo-l //-3-benzazepin-2-amines, e.g. 20a.41,42 l//-Naphtho[2,3-t/]azepines, e.g. 22a, are prepared in a similar manner from naphthalene-2,3-diacetonitriles, e.g. 21.41 Replacement of hydrogen bromide by hydrogen iodide yields the corresponding 4-iodo derivatives, e.g. 20b and 22b. 

Cyclization of l-bromo-19-methyl-1.19-dideoxybiladicnes-ac 11 to porphyrins 12 occurs simply by heating the tetrapyrrole in 1,2-dichlorobenzene solution or in few cases in dimethyl sulfoxide. 

The bromo substituent in l-bromo-19-meLhyl-l,l9-dideoxybiladienes- c is not essential for porphyrin formation. When 1-methylbiladiene-ac dihydrobromide or the 1,19-dimethyl-biladienc-ac are heated in refluxing methanol or dimethylformamide in the presence of cop-per(II) salts, the porphyrin copper complexes 13 are formed by oxidative cyclization. The free porphyrins can then be obtained by removal of the copper with acid. A wide range of porphyrins 13 can be prepared by this method. However, a restriction is the accessibility of the starting material with special substitution patterns. 

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