Aryl bromides cyclization

The allylstannane 474 is prepared by the reaction of allylic acetates or phosphates with tributyltin chloride and Sml2[286,308] or electroreduction[309]. Bu-iSnAlEt2 prepared in situ is used for the preparation of the allylstannane 475. These reactions correspond to inversion of an allyl cation to an allyl anion[3l0. 311], The reaction has been applied to the reductive cyclization of the alkenyl bromide in 476 with the allylic acetate to yield 477[312]. Intramolecular coupling of the allylic acetate in 478 with aryl bromide proceeds using BuiSnAlEti (479) by in situ formation of the allylstannane 480 and its reaction with the aryl bromide via transmetallation. (Another mechanistic possibility is the formation of an arylstannane and its coupling with allylic... 

The oxidative addition of palladium(O) to aryl bromide generates the arylpalladium(n) intermediate 126 (Scheme 37). The electrophilic activation of the double bond by palladium facilitates the nucleophilic attack, resulting in cyclization. 

With Pd(0) generated in situ, the oxidative addition of aryl bromide 102 to Pd(0) proceeds to form Pd(II) intermediate 104. Migratory insertion of 104 then occurs to furnish the cyclized indoline intermediate 105. Subsequent reductive elimination of 105 takes place in a cis fashion, giving rise to exo-cyclic olefin 107, which then tautomerizes spontaneously to the thermodynamically more stable indole 103. The reductive elimination by-product as a palladium hydride species 106 reacts with base, regenerating Pd(0) to close the catalytic cycle. 

Several intramolecular Heck reactions involve aryl halides cyclizing onto indole rings. Grigg first described the simple Heck cyclizations of 254 and 255 [270], and this was followed by similar Heck reactions reported by Kozikowski and Ma on the bromide corresponding to 254 and the IV-benzylindole 256 [271,272]. These investigators also observed cyclization to the C-3 position in a Heck reaction of indole 257, and they prepared a series of peripheral-type benzodiazepine receptors 258 using this chemistry. For example, 258 (n = 3, R = n-Pr) is obtained in 81% yield. 

Yang described the Pd-induced cyclization of an aryl bromide onto a pendant cyano group leading to y-carbolines and related compounds [488], Genet studied the use of chiral palladium complexes in the construction of the C-ring of ergot alkaloids, a study that culminated in a synthesis of (-)-chanoclavine I [489-491]. For example, nitroindole 388 is cyclized to 389 in 57% yield and with enantioselectivities of up to 95% using Pd(OAc)2 and (S)-(-)-BINAP. 

An unusual palladium-catalyzed arylative fragmenation process of /3-hydroxy-substituted allenes was observed by Oh et al. [59]. Compounds such as 8 reacted with aryl bromides and iodides in the presence of Pd(PPh3)4 and K2C03 as base to give 1,3-dienes 120 and aldehydes 121 as second fragment (Scheme 14.28). The initially expected cyclization product, dihydropyran 122 (Scheme 14.29), was usually not formed. 

Free-radical cyclization on to unsaturated CN bonds and also the cyclization of a range of nitrogen-centred radicals have continued to attract interest and have been reviewed. Aryl radicals, generated from BusSnH- or TTMSS-mediated homolytic cleavage of aryl-bromide bonds, have been shown to cyclize on to the nitrogen atom of imidate esters in the 5-exo mode (Scheme 9). Loss of an ethyl radical leads to the observed A-acylindolines. No cyclization in the 6-endo mode was detected. 

Once this process is explored with the model system to assess the level of enantioselectivity, we will then prepare alkyl zinc reagent 48 from 44 using standard methods - - and cross couple 48 to aryl bromide 18 using the appropriate chiral catalysts (Scheme 7). Although the acetonide stereocenter in 48 is somewhat remote from the coupling site, the stereocenter may serve to enhance the stereoselectivity of the cross-coupling process because the two possible products are diastereomers, not simply enantiomers. This reaction will produce 49 from (S)-48 and 30 from (R)-48 that can then be converted to epoxides 31 and 32 using standard methods. Epoxide 31 leads to heliannuol D 4 after base-promoted epoxide cyclization and deprotonation. Similarly, epoxide 32 leads to heliannuol A 1 after acid-promoted cyclization. 

Intramolecular group-transfer reactions can involve either direct displacements or addition-fragmentation reactions that are discussed in Section 4.2.4. A direct displacement is shown in the reaction of aryl radical 1, produced from the corresponding bromide. Cyclization of 1 is fast enough to compete efficiently... 

Free-radical cyclization reactions nicely complement the Pd(0)-catalyzed intramolecular Heck reaction, which also provides cyclic products from unsaturated halides. Free radicals can be generated easily at saturated carbons from saturated alkyl bromides, and the products are reduced relative to the reactants. In contrast, intramolecular Heck reactions work best for vinyl and aryl bromides (in fact they do not work for alkyl halides), and the products are at the same oxidation level as the reactants. Moreover, free radicals attack the double bond at the internal position, whereas palladium insertion causes cyclization to occur at the external carbon. 

Intramolecular addition of vinyl radicals to olefins as a method for heterocycle synthesis has been examined. The vinyl radicals can be conveniently generated from vinyl bromides and samarium(II) diiodide [95JOC7424], The intermediate radical after cyclization undergoes a further electron transfer from samarium to furnish a carbanion which is quenched at the end of the reaction. A samarium(II) diiodide mediated aryl radical cyclization onto a dihydrofuran has been reported [95T8555],... 

Intramolecular radical cyclization of an aryl bromide and an alkyne can be used to produce dihydroquinolines (Equation 57) <1998TL2965>. An analogous reaction setup utilizes a Lewis acid-catalyzed novel one-pot domino pathway using silver catalysis in high regioselectivity (Scheme 26) <2005OL2675>. Three mole equivalents of the alkyne are used with the final cyclization step arising from alkynic addition. 

Alkyl and aryl radical cyclizations were developed using catalytic amounts of MnCl2 and butylmagnesium bromide as a stoichiometric reductant (Fig. 44)... 

Treatment of the aryl bromide 429 with Bu Li generates a dilithiated compound that undergoes oxidative intramolecular cyclization with CuCl2 to afford fused thiophene 430 (Scheme 69) <20040L4179>. Similar syntheses of pentathio-noacene 432 <2005JA13281> from 431 and heptathionoacene 434 <2005JA10502> from 433 have heen reported. 

The BINAP/Pd- and DPPF/Pd-catalyst systems have been used by numerous groups to react aryl bromides with arylamines. Ward and Farina as well as Willoughby and Chapman performed the arylation reaction with arylamines and resin-bound aryl bromides [31,32]. Snieckus reported the use of the Pd-cat-alyzed C-N bond forming reaction to prepare several acridone derivatives, Eq. (81) [92]. Kamikawa et al. prepared phenazine derivatives via an initial C-N bond coupling and subsequent cyclization, Eq. (82) [93]. 

N-Arylindoles could be prepared via a one-pot sequential arylation of benzophenone hydrazone. For example, after the first C-N bond coupling with the less reactive aryl bromide was performed with the 9/Pd-catalyst after complete reaction, the second aryl bromide was then introduced to the reaction mixture, Eq. (150) [121]. The doubly arylated product could be cyclized to yield the desired N-arylindole in moderate to good yield. 

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