Aldehydes radical generation from

Intramolecular addition of trialkylboranes to imines and related compounds have been reported and the main results are part of review articles [94, 95]. Addition of ethyl radicals generated from Et3B to aldimines affords the desired addition product in fair to good yield but low diaster control (Scheme 40, Eq. 40a) [96]. Similar reactions with aldoxime ethers [97], aldehyde hydrazones [97], and N-sulfonylaldimines [98] are reported. Radical addition to ketimines has been recently reported (Eq. 40b) [99]. Addition of triethylborane to 2H-azirine-3-carboxylate derivatives is reported [100]. Very recently, Somfai has extended this reaction to the addition of different alkyl radicals generated from trialkylboranes to a chiral ester of 2ff-azirine-3-carboxylate under Lewis acid activation with CuCl (Eq. 40c) [101]. 

Minisci-type substitution is one of the most useful reactions for the synthesis of alkyl- and acyl-substituted heteroaromatics. The acyl radicals are formed by the redox decomposition from aldehyde and /-butyl hydroperoxide or by silver-catalyzed decarboxylation of a a-keto acid with persulfate. Synthesis of acylpyrazines 70 as ant pheromones are achieved by this methodology using trialkyl-substituted pyrazines 69 with the acyl radicals generated from aldehydes or a-keto acids (Equation 10) <1996J(P1)2345>. The latter radicals are highly effective for the acylation. Homolytic alkylation of 6-chloro-2-cyanopyrazine 71 is performed by silver-catalyzed decarboxylation of alkanoic acids to provide 5-alkyl-substituted pyrazines 72 (Scheme 18) <1996CCC1109>. 

A new process for the homolytic acylation of protonated heteroaromatic bases has been developed by Minisci et al. An A-oxyl radical generated from iV-hydroxyphthalimide by oxygen and Co(ll) abstracts a hydrogen atom from an aldehyde. The resulting nucleophilic acyl radical adds to the heterocycle which is then rearomatized via a chain process. Under these conditions, quinoline and benzaldehyde afford three products (Equation 108) <2003JHC325>. A similar reaction with 4-cyanopyridine gives 2-benzoyl-4-cyanopyridine in 96% yield. 

Benzothiazole is acylated selectively in the 2-position by acyl radicals generated from a variety of aldehydes under the influence of the redox system f-butylhydroperoxide-ferrous sulfate. The nucleophilicity of acyl radicals is confirmed by the higher reactivity of 6-nitrobenzothiazole. The reaction, which could detect acyl radicals in the oxidation of aldehydes by various oxidizing agents, could serve as a diagnostic test for the presence of such radicals (71JCS(C)1747). 

Acyl radical sources, other than aldehydes, are also available. The group transfer addition of an acyl radical has been reported by Zard and co-workers, where S-acyl xanthates serve as acyl radical sources [44]. Crich and co-workers reported that an acyl radical, generated from an aromatic acyl telluride by photolysis, adds to an allylic sulfide which contains an ethoxycarbonyl group to form the corre-.sponding y-unsaturated ketones [45]. The addition pathway involves Sh2 type reaction with extrusion of a /ert-butylthiyl radical. 

Few examples of what might be described as an intermolecular coupling reaction on inactivated alkenes has appeared [62], Thus ketyl radicals generated from aromatic aldehydes and ketones underwent intermolecular addition to the para position of another aldehyde. Cross-coupling reactions are not feasible in these systems and typically yields are quite low. 

A problem with this methodology is that only one of the three alkyl groups is transferred to the unsaturated carbonyl compound. A solution to this uses the radical generated from the boronic ester, itself derived from hydroboration with catecholb-orane 8. Treatment of the boronic ester with oxygen and 1,3-dimethyl-hexahydro-2-pyrimidinone (DMPU) in the presence of the a,3-unsaturated aldehyde or ketone gives the desired radical addition product, with transfer of the S-alkyl group. Thus, cyclohexene was converted to l-cyclohexyl-3-pentanone 24 using this chemistry (5.38). 

Caddick et al. have successfully applied the aerobic acylation of the electron-deficient vinyl phosphonates (668) by acyl radicals generated from aldehydes (669) via their auto-oxidation, to the synthesis of y-ketophos-phonates (670) (Scheme 168) ... 

Addition of Vinyl and Aryl Groups. The reaction of aromatic radicals, generated by decomposition of diazonium salts, with iminium salts in the presence of TiCE in aqueous media produces secondary amines (Eq. 11.53).91 The iminium salts are formed in situ from aromatic amines and aldehydes. 

The a,( -unsaturated aldehyde 452 is generated from the unstable spiro-oxetane 451, and hydrogen abstraction from the aldehydic C-H bond by 3449 gave a triplet radical pair 453 and 454. Intersystem crossing and radical recombination followed by intramolecular nucleophilic attack of the hydroxyl group toward the ketene functionality furnish the diastereomeric products 54 and 55 (Scheme 102) <20000L2583>. 

In a related study, the oxidation-reduction sequence was carried out in the presence of an olefin (Scheme 21). Two products were formed. The major product resulted from the net reduction of the carboxylic acid to an aldehyde. The minor product resulted from trapping of the radical anion intermediate generated from the reduction reaction by the olefin. It should be noted that, in the absence of a trapping group, the acid can be selectively reduced to the aldehyde without any over-reduction. Although not in the scope of this review, this is a very useful transformation in its own right [35]. At this time, the yields of the cyclized products from the cyclization reaction of the radical anion with the olefin remain low. 

The stereoselective nature of the reaction supports the suggestion that epoxidation in this case does not occur by acylperoxy radicals but rather by peracids generated from autoxidation of aldehydes. 

The following mechanism is suggested as operating in the conversion of XXXII to XXXIV. If the radical (XXX) is assumed to be generated from a p-hydroxybenzyl alcoholic end group, the cyclohexadienone system (XXXII) would carry an a-hydroxyl-substituted side chain. Removal of the latter as an aldehyde (XXXIII) might then occur, as indicated by the arrows in formula (XXXII). 

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