Radical cyclizations acyl radicals

Radical cyclization. Acyl radicals are gene (MCjSijjSiH in the presence of EtjB at or below n to a juxtaposed conjugated ester to form a cvcIk Substituents at the y and 5 positions of the ester uni mode. Triorganotin hydrides can also be used. 1... 

Tris[(2-perfluorohexyl)ethyl]tin hydride has three perfluorinated segments with ethylene spacers and it partitions primarily (> 98%) into the fluorous phase in a liquid-liquid extraction. This feature not only facilitates the purification of the product from the tin residue but also recovers toxic tin residue for further reuse. Stoichiometric reductive radical reactions with the fluorous tin hydride 3 have been previously reported and a catalytic procedure is also well established. The reduction of adamantyl bromide in BTF (benzotrifluoride) " using 1.2 equiv of the fluorous tin hydride and a catalytic amount of azobisisobutyronitrile (AIBN) was complete in 3 hr (Scheme 1). After the simple liquid-liquid extraction, adamantane was obtained in 90% yield in the organic layer and the fluorous tin bromide was separated from the fluorous phase. The recovered fluorous tin bromide was reduced and reused to give the same results. Phenylselenides, tertiary nitro compounds, and xanthates were also successfully reduced by the fluorous fin hydride. Standard radical additions and cyclizations can also be conducted as shown by the examples in Scheme 1. Hydrostannation reactions are also possible, and these are useful in the techniques of fluorous phase switching. Carbonylations are also possible. Rate constants for the reaction of the fluorous tin hydride with primary radicals and acyl radicals have been measured it is marginally more reactive than tributlytin hydrides. ... 

A further variant on the radical carbonylation/acyl radical cyclization theme involves the silylcarbonylation of 1,5-hexadienes [48]. Here, the sequence is initiated by the addition of a tris(trimethylsilyl)silyl radical to the least substituted terminus of the diene. Carbonylation and acyl radical cyclization then ensues in the normal way. It should be noted that this type of carbonylation cannot be achieved with tin hydride, since the carbonylation rate is not sufficient to capture y -tin-attached alkyl radical, which quickly reverts to tin radical and the 1,5-diene. 

Scheme 5.10 Samarium(ll) iodide-induced domino radical cyclization/acylation reaction.

A possible mechanism for the formation of the furanones 6 and 7 is illustrated in Scheme 2. The initial alkoxy radical generated from the alcohol 5 and lead tetraacetate (LTA) undergoes /3-scission to produce the acyl radical intermediate 9. Subsequent cyclization to 10 proceeds through attack of the radical at the carbonyl oxygen. The resulting Pb(IV) intermediate 11 finally collapses via the reductive... 

Radical cascades that feature a 7-exo acyl radical cyclization followed by a 6-exo or 5-exo alkyl radical cyclization proceed with very good yields and diastereoselectivities. Two examples are shown in Reaction (80), where treatment of 100 with E3B, air, and (TMS)3SiH provided the tricycle 101 in excellent yields as a single diastereomer. Interestingly, the bulky silyl ether moiety is not required to achieve stereoselectivity in this process. 

Acyl radicals can be generated and they cyclize in the usual manner. A polyene-cyclization reaction generated four rings, initiating the sequence by treatment of a phenylseleno ester with Bu3SnH/AIBN to form the acyl radical, which added to the first alkene unit. The newly formed carbon radical added to the next alkene, and so on. Acyl radicals generated firom Ts(R)NCOSePh derivatives cyclize to form lactams. ... 

Cyclization of both alkyl and acyl radicals generated by selenide abstraction have also been observed. 

Entry 11 involves generation and cyclization of an alkoxymethyl radical from a selenide. The cyclization mode is the anticipated 5-exo with a cis ring juncture. This is a case in which the electronic characteristics of the radical are not particularly favorable (ERG oxygen in the radical), but cyclization nevertheless proceeds readily. The reaction in Entry 12 was used to prepare a precursor of epibatidine. Entry 13 shows a 6-endo cyclization that is favored by steric factors. The 6-endo cyclization is also favored with a tetrahydropyranyloxy substituent in place of the ester, indicating that the electronic effect is not important. Entries 14 to 16 involve acyl radicals generated from selenides. The preferred 6-endo cyclization in Entry 15 is thought to be due to the preference for the less-substituted end of the double bond. Entry 17 is an example of a 5-exo-dig cyclization. 

The unexpected formation of cyclopenta[b]indole 3-339 and cyclohepta[b]indole derivatives has been observed by Bennasar and coworkers when a mixture of 2-in-dolylselenoester 3-333 and different alkene acceptors (e. g., 3-335) was subjected to nonreductive radical conditions (hexabutylditin, benzene, irradiation or TTMSS, AIBN) [132]. The process can be explained by considering the initial formation of acyl radical 3-334, which carries out an intermolecular radical addition onto the alkene 3-335, generating intermediate 3-336 (Scheme 3.81). Subsequent 5-erafo-trig cyclization leads to the formation of indoline radical 3-337, which finally is oxidized via an unknown mechanism (the involvement of AIBN with 3-338 as intermediate is proposed) to give the indole derivative 3-339. 

Sometimes acylium ions lose carbon monoxide to generate an ordinary carbonium ion. It will be recalled that free acyl radicals exhibit similar behavior at high temperatures. Whether or not the loss of carbon monoxide takes place seems to depend on the stability of the resulting carbonium ion and on the speed with which the acylium ion is removed by competing reactions. Thus no decarbonylation is observed in Friedel-Crafts reactions of benzoyl chloride, the phenyl cation being rather unstable. But attempts to make pivaloyl benzene by the Friedel-Crafts reaction produce tert-butyl benzene instead. With compound XLIV cyclization competes with decarbonylation, but this competition is not successful in the case of compound XLV in which the ring is deactivated.263... 

Table 8. Cyclization of carboxylic acids onto alkenes acyl radical synthon...

The cyclization of 8, s-unsaturated acyl radicals has been the research subject of several groups [27]. The propagation steps for the prototype reaction are illustrated in Scheme 7.4. The 5-exo 6-endo product ratio varies with the change of the silane concentration due to the competition of hydrogen abstraction from the silane with the ring expansion path. 

Scheme 7.4 Propagation steps involving the cyclization of acyl radicals...

A series of experiments were effected performing the photolysis in the presence of thiophenol, TEMPO, PhSeSePh and, PhSSPh where the radical captors compete with the 6-exo-cyclization in trapping the acyl radical. ... 

A novel tandem carbonyiation/cyclization radical process has been developed for the intramolecular acylation of l-(2-iodoethyl)indoles and pyrroles <99TL7153>. In this process, an acyl radical is formed when CO is trapped by an alkyl radical formed from the AIBN-induced radical reaction of l-(2-iodoethyl)indoles 104 with BusSnH. Intramolecular addition of the acyl radical to the C-2 position of the heteroaromatic system presumably affords a benzylic radical which undergoes in situ oxidative rearomatization to the bicycloketones 105. 

An interesting strategy for pyrrolidine a,/3-functionalization has been developed <2005T1221>, starting from readily available endocyclic enamine derivatives. A two-step heteroannulation procedure involving iodoetherification of A -acyl-2-pyrrolines 216 giving 217 followed by radical cyclization gave access to the bicyclic compounds 218 which can be used in further transformations to form substituted pyrrolidines 219 and 220 (Scheme 22). 

Another way to construct alkenes is by the addition of carbon radicals to nitrostyrenes such as 5. Ching-Fa Yao of National Taiwan Normal University in Taipei has reported (J. Org. Chem. 2004,69, 3961) an extension of this work, generating the acyl radical from the aldehyde 6, cyclizing it to generate a new radical, then trapping that radical with 5 to give 7. This article includes an overview of the several ways of adding radicals to 5. 

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