From aryl nitriles

Cycloaddition of 2-nitrosopyridine 48 with nitrile oxides can give either di-A -oxides such as 49 or 3-mono-A -oxides such as 50 (93JHC287). In general, greater electron withdrawing character in the aromatic substituent appears to favor formation of the di-A -oxides. Sulfur ylides such as compound 51 are obtained from aryl isothiocyanates and l-amino-2-methylthiopyridinium iodides (84JCS(P1)1891) nitrogen ylides can be obtained from a similar reaction (86H(24)3363). 

The first synthesis of a 3,5-diarylisoxazole from aryl hydroxamic acid chlorides and sodium phenyl acetylides was that effected by Weygand and Bauer in 1927. Beginning in 1946, when Quilico and Speroni showed that acid chlorides of hydroxamic acids on treatment with alkalies readily yielded nitrile oxides,numerous isoxazole and especially A -isoxazoline derivatives have been prepared. 

It was found that the reaction of 5-acetoxy- and 5-benzoyloxy-2(5//)-furanones 174 with aryl nitrile oxides afforded only one cycloadduct, the condensed isox-azoline 233 (88TL5317). In principle, there are four possible cycloadducts 233 and 234 resulting from the anti approach of the 1,3-dipolarophile to the acetoxy group (with exo configuration of the acetoxy substituent), and two further isomers... 

Arylthallium bis(trifluoroacetates) (see 12-21) can be converted to aryl nitriles by treatment with copper(I) cyanide in acetonitrile. Another procedure uses excess aqueous KCN followed by photolysis of the resulting complex ion ArTl(CN)3 in the presence of excess KCN. Alternatively, arylthallium acetates react with Cu(CN)2 or CuCN to give aryl nitriles. Yields from this procedure are variable, ranging from almost nothing to 90 or 100%. 

Catalytic enantioselective crossed aldehyde-ketone benzoin cyclizations of ketoaldehydes, such as 13, readily obtained from an aryl nitrile oxide and a 1,3-diketone, were studied in order to perform the synthesis of complex molecules. Significant asymmetric induction was observed with chiral triazolium salts such as 14, in the presence of DBU as base, leading to compound 15 in high yield and with 99% ee in favor of the R enantiomer <06AG(E)3492>. 

The tetrachloroferrate or tetralluoroborate salts of alkylated alkyl- or aryl-nitriles (nitrilium ions) are reduced to imines with triethylsilane. Subsequent hydrolysis of the intermediate imines leads to aldehydes in good yields, thus providing an excellent overall route to aldehydes from nitriles (Eq. 338).28,562... 

Alkyl and aryl nitriles 151 react with thiosemicarbazide 138 under acidic conditions to give 1,3,4-thiadiazoles (Scheme 14 and Table 8) <1995BML1995, 1996IJB273, 1997IJB394>. The acidic conditions promote the elimination of ammonia from the intermediate iminothioacylhydrazine 152. 

Isoxazolines 79, obtained from aromatic nitrile oxide cycloadditions to cyclohex-2-enone, reacted with nickel peroxide to give 3-aryl-6,7-dihydro[l] benzoisoxazol-4(5// )-ones 80. In contrast, the corresponding 2-bromocyclohex-2-enone underwent nitrile oxide cycloaddition, followed by dehydrobromination, to afford the regioisomeric 3-aryl-4,5-dihydro[l]benzoisoxazol-7(6//)-ones 81 (Scheme 1.23) (242). 

This work has been extended from aryl and alkyl substituted systems (42) (R = aryl, alkyl) to analogues where R is an amino group, so giving access to synthetic equivalents of the nonstabilized amino nitrile ylides (45). Adducts were obtained in good-to-moderate yield with A-methyhnaleimide (NMMA), DMAD, electron-deficient alkenes and aromatic aldehydes (27,28), and with sulfonylimines and diethyl azodicarboxylate (29). Similarly the A-[(trimethylsilyl)methyl]-thiocarbamates (46) undergo selective S-methylation with methyl triflate and subsequent fluorodesilylation in a one-pot process at room temperature to generate the azomethine ylides 47. 

Kurabayashi and Grundmann have reported the preparation of the 1,2,4-oxadiazoles (34) from 1,3,5-triazine and aryl nitrile oxides in the presence of boron trifluoride. The mechanism has not been fully elucidated, but it is most likely that the initial stage is the formation of the complex (33) (78BCJ1484). 

Dicyandiamide (116) reacts with a variety of two-atom components to form 2,4-diamino-1,3,5-triazines. The route, which bears some resemblance to the syntheses from biguanides (see Section 2.20.4.2.1), was discovered by Ostrogovich (11MI22000). He found that 1,3,5-triazines were prepared efficiently on heating alkyl or aryl nitriles with dicyandiamide (equation 59). 

This route is particularly valuable for substituents that cannot easily be added by electrophilic substitution such as OH or CN. Table 2.2 gives you a selection of reagents. For the addition of CN, Cl or Br, copper (I) derivatives usually give the best results. So the aryl nitrile 46 might come from amine 47 via a diazonium salt and routine disconnections lead us back to toluene. 

ArC=N.1 Aryl triflates react with KCN at 60° in CH3CN in the presence of Ni(0) (5 mole %), generated in situ from Br2Ni[P(C6H5)3]2 and zinc, to form aryl nitriles in 69-78% yield. This coupling is not useful in the case of haloary 1 triflates because of coupling of KCN with the halo groups. Pd catalysts are not useful. 

Carbanions from hydrocarbons, nitriles, ketones, esters, TV./V-dialkyl acetamides and thioamides, and mono and dianions from (3-dicarbonyl compounds are some of the most common nucleophiles through which a new C-C bond can be formed. This C-C bond formation is also achieved by reaction with aromatic alkoxides. Among the nitrogen nucleophiles known to react are amide ions to form anilines however, the anions from aromatic amines, pyrroles, diazoles and triazoles, react with aromatic substrates to afford C-arylation. 

Similar [3 4-2] cycloadditions with C-aryl nitrile oxides and other terminal fiuoroalkylated al-kenes (RF = C2F5, C6F13) and fiuoroalkylated alkynes provide high yields of cycloadducts.86,87 The nitrile oxides can be generated by various methods. Generation from bromoaldoximes in a chloroform/sodium hypochlorite biphase medium is efficient.86... 

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