Azirines rearrangement

The kinetics of a further series of isoxazole-2//-azirine rearrangements at 165-185°C has been investigated.62 The activation parameters for 3-phenyl-5-methoxyisoxazole (AH = 38 + 1 kcal/mol AS = 3.6 2 eu) are in good accord with the postulated initial N—O bond breakage [DH°(PhO— NR2) = 38-39 kcal/mol63]. The photochemical64 and thermal65 conversion of benzisoxazoles to benzoxazoles appears to involve an intermediate spiroazirine. 

An elegant application of the isoxazole -azirine rearrangement has been used in the generation of the fused azirine 64 which, on further photolysis, underwent ring expansion to the cyclic ketenimine 65 as shown in Eq. (19).66... 

Reactions of Isoxazoles. The kinetics of the isoxazole azirine rearrangement (336) -> (337) and those of the isoxazole oxazole transformation (338) (339) have been determinedPalladium(II) chloride-triphenyl-phosphine catalyses the cross-coupling of 4-iodo-3,5-dimethylisoxazole with styrene to yield the trans- compound (340). 3,5-Dimethylisoxazole can be lithiated in two stages, first at the 5-methyl group and then at the 3-methyl group. Isoxazoles add hypochlorous acid to form 4-chloro-2,3-dihydro-... 

It was shown that 1-azirines can serve as precursors to vinylnitrenes. A number of 1-azirines rearrange to indoles, most likely via vinylnitrene intermediates, upon heating. Two examples are known in which the nitrene formed during the thermolysis of azirines can be intercepted by tris(dimethy-lamino)phosphine or triphenylphosphine. ... 

The kinetics of a further series of isoxazoIe-2//-azirine rearrangements at 165-185°C has been investigated. The activation parameters for 3-phenyl-... 

The pyrazole ring is resistant to oxidation and reduction. Only ozonolysis, electrolytic oxidations, or strong base can cause ring fission. On photolysis, pyrazoles undergo an unusual rearrangement to yield imidazoles via cleavage of the N —N2 bond, followed by cyclization of the radical iatermediate to azirine (27). 

Important synthetic paths to azirines and aziridines involve bond reorganization, or internal addition, of vinylnitrenes. Indeed, the vinylnitrene-azirine equilibrium has been demonstrated in the case of trans-2-methyl-3-phenyl-l-azirine, which at 110 °C racemizes 2000 times faster than it rearranges to 2-methylindole (80CC1252). Created in the Neber rearrangement or by decomposition of vinyl azides, the nitrene can cyclize to the p -carbon to give azirines (Scheme 4 Section 5.04.4.1). 

Whereas the cycloaddition of arylazirines with simple alkenes produces A -pyrrolines, a rearranged isomer can be formed when the alkene and the azirine moieties are suitably arranged in the same molecule. This type of intramolecular photocycloaddition was first detected using 2-vinyl-substituted azirines (75JA4682). Irradiation of azirine (54) in benzene afforded a 2,3-disubstituted pyrrole (55), while thermolysis gave a 2,5-disubstituted pyrrole (56). Photolysis of azirine (57) proceeded similarly and gave 1,2-diphenylimidazole (58) as the exclusive photoproduct. This stands in marked contrast to the thermal reaction of (57) which afforded 1,3-diphenylpyrazole (59) as the only product. 

The thermal transformations observed with these systems can be rationalized in terms of an equilibration of the 1-azirine with a transient vinylnitrene which subsequently rearranges to the 2,5-disubstituted pyrrole (56). 

The 1-azirines obtained from the vapor phase pyrolysis of 4,5-disubstituted 1-phthalimido-1,2,3-triazoles (157) have been found to undergo further thermal reactions (71CC1S18). Those azirines which contain a methyl group in the 2-position of the ring are cleaved to nitriles and phthalimidocarbenes, whereas those azirines which possess a phenyl substituent in the 2-position rearrange to indoles. 

Addition of trichloromethide ion to azirine (210) generates aziridine (230). When this aziridine was treated with base, cyclization and rearrangement occurred and the azetidine (233) was isolated (73JA2982). 

One of the more important approaches to 1-azirines involves a similar base-induced cycloelimination reaction of a suitably functionalized ketone derivative (route c. Scheme 1). This reaction is analogous to route (b) (Scheme 1) used for the synthesis of aziridines wherein displacement of the leaving group at nitrogen is initiated by a -carbanionic center. An example of this cycloelimination involves the Neber rearrangement of oxime tosylate esters (357 X = OTs) to 1-azirines and subsequently to a-aminoketones (358) (71AHC-(13)45). The reaction has been demonstrated to be configurationally indiscriminate both syn and anti ketoxime tosylate esters afforded the same product mixture of a-aminoketones... 

Azirine, C-acyl-rearrangement oxazoles from, 6, 223 Azirine, allyl-... 

Azirine, trans-2-methyl-3-phenyl-racemization, 7, 33, 34 1-Azirine, 2-phenyl-reactions, 7, 69 with carbon disulfide, S, 153 1-Azirine, 3-vinyl-rearrangements, 7, 67 Azirines, 7, 47-93 cycloaddition reactions, 7, 26 fused ring derivatives, 7, 47-93 imidazole synthesis from, 5, 487-488 photochemical addition reactions to carbonyl compounds, 7, 56 photolysis, 5, 780, 7, 28 protonated... 

Rearrangement of N.N-dimethyttiydrazone or tosylate derivatives of oxime to azirines and from there to a-amino ketones. 

The 3//-azepines obtained by cycloaddition of azirines to cyclopentadienones (see Section 3.1.1.1.2.) are thought to arise from the initially formed 2/7-azepines by [1,5]-H suprafacial sigmatropic shifts.31-108 In contrast, 1/Z-azepine 9 results from the thermal rearrangement of the nonisolable 2//-azepine-2-carboxylate 8.13 Presumably, the 1 //-azepine is stabilized, relative to the 3//-isomer, by intramolecular hydrogen bonding between the NH and the adjacent ester group. 

Oxazole formation can be envisaged as proceeding by three possible pathways 1,3-dipolar cycloaddition of a free ketocarbene to the nitiile (Path A), the formation and subsequent 1,5-cyclisation of a nitrile ylide (Path B) or the formation and subsequent rearrangement of a 2-acyl-2//-azirine (Path C) (Scheme 9). 

Although 2-acyl-2//-azirines are known to give oxazoles upon irradiation, the reaction is wavelength dependent, and isoxazoles are formed at some wavelengths, as they are in the thermal rearrangement of 2-acyl-2//-azirines.<74TL29,75JA4682> Since the thermal reaction of diazocarbonyl compounds with nitriles leads to oxazole formation, it would seem that mechanistic path C is unlikely in these reactions. 

Bromo-j3-nitrostyrene and triphenylphosphine in dry benzene gave the phosphonium bromide (47). Using methanol as the solvent, the rearranged product (48) was formed, possibly via an azirine intermediate. Substituted -bromo-/3-nitrostyrenes yield the phosphoranes (49) and a phosphonium salt. When the aryl group is electron-donating, the reaction follows a different course to form the styrene (50) by initial attack of the phosphine on halogen. 

The reverse process has also been examined. 2-Phenyloxazole is converted in a similar fashion to 3-phenyl-2//-azirine-2-carbaldehyde on irradiation in benzene or cyclohexane.128 Further rearrangement to the corresponding isoxazole can be effected thermally but not photochemically. A competing pathway leading to the formation of 4-phenyloxazole has also been observed and is thought to involve a bicyclic intermediate arising by 2,5-bonding. 

Taber and Tian have employed the Neber protocol to prepare a-aryl azirines that underwent thermal rearrangement to afford substituted indoles via a unique Ie type ring closure <06JACS1058>. A variety of substituted N-alkyl and N-aryl indoles have been prepared by Zhao and co-workers who observed Ie cyclization of 2-aryl-3-arylamino-2-... 

Although highly reactive, 2/7-azirines are of considerable synthetic interest and serve as a source of the 3-fluoro-4//-l, 3-diazepines 86. Reaction of 80 with difluorocarbene in the presence of furfural gave 86, rather than the expected furfural-derived products 83. Rearrangement of the initial 1,3-dipolar intermediate 81 to 84 and then cycloaddition of 84 with 80 are proposed as key steps in the reaction the intermediate cycloadduct 85 gave 86 on base-induced elimination of HF. Nucleophilic displacement of the fluoro group in 86 provided access to further substituted 1,3-diazepines <06TL639>. 

Our calculations on the ring expansion of the lowest singlet state of phenylnitrene ( A2-lb) to azacycloheptatetraene (3b) predict a two-step mechanism that is analogous to that for the rearrangement of la to 3a and which involves the bicyclic azirine intermediate 2b.61 The CASPT2 energetics are depicted in Fig. 5, and the CASSCF optimized geometries of the stationary points are shown in Fig. 6. 

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