Hydrazones rearrangement

Clean examples of diaziridine to hydrazone rearrangements are rare. Diaziridine (119) mentioned above rearranges to the isomeric enhydrazone in boiling toluene, and 2,4-dinitrophenyldiaziridine (125) under the same conditions affords the 2,4-dinitrophenylhy-drazone (145) within 4 h. On blocking this rearrangement by iV-methyl, conversion with loss of cyclohexanone occurred to give benzotriazole iV-oxide (146) (72JOC2980). 

Cleavage of carbonyl-containing selenoxides and sulfones Fragmentation of epoxy hydrazones Rearrangement of vinylic hydroxycyclopropanes Rearrangement of 3-hydroxy-1,5-dienes (oxy-Cope)... 

Af, A -Disubstituted hydrazones rearrange smoothly to furnish 1,2,3-triazolium salts, hydrazides give triazolones (35), and amidrazones (36) afford (37) (Scheme 12) <91KGS822,92KGS969). 

The sodium salt of the JV-methoxycarbonyl hydrazone rearranges faster than the hydrazone itself or the parent ketone. This method has been used for the construction of vicinal quaternary centers, since the accelerating functionality can simply be removed by Wolff Kischner reduction. For charge-accelerated Claisen rearrangements of related systems see refs 85 and 113— 118. 

Examples of three different oxidant-promoted iV-allylic hydrazone rearrangements developed by the Thomson group are illustrated in Scheme 14.19a. These transformations convert N-allylic hydrazones to homoallylic halides in the presence of either CUCI2 or NBS and to... 

The oxidation of N-amino-3-azabicyclo[3.3.0]octane by chloramine proceeds in several steps. The reaction passes by a diazene intermediate, which decomposes according to two competitive way leading to 3,4-diazabicyclo[4.3.0]non-2-ene and N,N -azo-3-azabicyclo-[3.3.0]octane. The kinetic study shows that the first step is bimolecular and exhibits a specific acid catalysis. The difficulty of this study results from impossibility to follow the diazene content according to time. To determine the kinetic laws of diazene-hydrazone rearrangement, a specific procedure based on the degeneration of the precursor process was developped. 

To favour the formation of the endocyclic hydrazone, it is necessary to know the kinetics of aminonitrene-hydrazone rearrangement. The difficulty of this study results from impossibility to follow the diazene content according to time. The kinetic parameters are thus determined by degeneration of the precursor process (1). 

Anomalous Fischer cyclizations are observed with certain c-substituted aryl-hydrazones, especially 2-alkoxy derivatives[l]. The products which are formed can generally be accounted for by an intermediate which w ould be formed by (ip50-substitution during the sigmatropic rearrangement step. Nucleophiles from the reaction medium, e.g. Cl or the solvent, are introduced at the 5-and/or 6-position of the indole ring. Even carbon nucleophiles, e.g. ethyl acetoacelate, can be incorporated if added to the reaction solution[2]. The use of 2-tosyloxy or 2-trifluoromethanesulfonyloxy derivatives has been found to avoid this complication and has proved useful in the preparation of 7-oxygen-ated indoles[3]. 

Production is by the acetylation of 4-aminophenol. This can be achieved with acetic acid and acetic anhydride at 80°C (191), with acetic acid anhydride in pyridine at 100°C (192), with acetyl chloride and pyridine in toluene at 60°C (193), or by the action of ketene in alcohoHc suspension. 4-Hydroxyacetanihde also may be synthesized directiy from 4-nitrophenol The available reduction—acetylation systems include tin with acetic acid, hydrogenation over Pd—C in acetic anhydride, and hydrogenation over platinum in acetic acid (194,195). Other routes include rearrangement of 4-hydroxyacetophenone hydrazone with sodium nitrite in sulfuric acid and the electrolytic hydroxylation of acetanilide [103-84-4] (196). 

Pyridazines are formed from pyrones or their thioxo analogs or from appropriate pyridones. Pyrones or pyridones react with diazonium salts to give the corresponding hydrazones (187) and (188) which are rearranged under the influence of acid or base into pyridazinones as shown in Scheme 107. On the other hand, kojic acid is transformed with hydrazine into a 1,4-dihydropyridazine and a pyrazole derivative. 4H-Pyran-4-thiones... 

A different type of rearrangement occurs when suitable side chains are a to a pyridine-like nitrogen atom. In the monocyclic series this can be generalized by Scheme 43. For a given side chain the rate of rearrangement is l,2,4-oxadiazoles>isoxazoles> 1,2,5-oxadiazoles. Typical side chains include hydrazone, oxime and amidine. Some examples are shown in Table 9 (79AHC(25)147). Similar rearrangements for benzazoles are discussed in Section 4.02.3.2.4. 

While the use of substituted hydrazine derivatives is generally recognized to be the most reliable method for dehydrobromination of bromo ketones without rearrangement, this side reaction can be important in some cases. Both the 2-bromo-A" -3-ketone and its 4-bromo isomer give the same A" -diene hydrazone (33), °° which is cleaved to the ketone in very poor yield (however, see ref. 65 for a successful use of the semicarbazide method). 

Hexafluoroacetone azine accepts nucleophiles (ROH, RSH, R NH) in positions 1 and 2 to yield hydrazones [27] Phosphites give open-chain products via a skeletal rearrangement [22] Radical addition reactions are also reported [22] Treatment of tnfluoropyruvates with tosylhydrazine and phosphorus oxychlo-ride-pyndme yields tnfluoromethyl-substituted diazo compounds [24] (equation 3)... 

The coupling of enamines with aromatic diazonium salts has been used for the syntheses of monoarylhydrazones of a-diketones (370,488-492) and a-ketoaldehydes (488,493). Cleavage of the initial enamine double bond and formation of the phenylhydrazone of acetone and acetophenone has been reported with the enamines of isobutyraldehyde and 2-phenylpropionalde-hyde. Rearrangement of the initial coupling product to the hydrazone tautomer is not possible in these examples. 

A number of reaction pathways have been proposed for the Fischer indolization reaction. The mechanism proposed by Robinson and Robinson in 1918, which was extended by Allen and Wilson in 1943 and interpreted in light of modem electronic theory by Carlin and Fischer in 1948 is now generally accepted. The mechanism consists of three stages (I) hydrazone-ene-hydrazine equilibrium (II) formation of the new C-C bond via a [3,3]-sigmatropic rearrangement (III) generation of the indole nucleus by loss of... 

Another example of this rearrangement has been used to prepare 1,2,3-triazole 146 from furazanic phenylhydrazone 147 (Scheme 84) [93JCS(P1)2491]. Interestingly, furoxanic Z-phenylhydrazones 150 underwent thermal recyclization to 1,2,3-triazole A-oxides 152, evidently through intermediate 151. Treatment of the hydrazone 150 with rerr-BuOK leads to the nitromethyl derivative 149 [OOOMIl] (Scheme 84). Lead tetraacetate oxidation of 147 with subsequent Lewis acid treatment of the initially formed intermediate afforded indazole 148 (Scheme 84) (85JHC29). 

Heating of an aryl hydrazone 1 in the presence of a catalyst leads to elimination of ammonia and formation of an indole 2. This reaction is known as the Fischer indole synthesisy and is somewhat related to the Benzidine rearrangement. 

A mechanism, that has been proposed by G. M. Robinson and R. Robinson, consists of three steps. Initially the phenyl hydrazone 1 undergoes a reversible rearrangement to give the reactive ene-hydrazine 3 ... 

Thus, acetylation of aniline affords acetanilide (20), an analgesic widely used in proprietary headache remedies. A similar transformation on p-aminophenol gives the analgesic, acetaminophen (21). It is of interest that the latter is also formed in vivo on administration of 21. An interesting preparation of this drug involves Schmidt rearrangement of the hydrazone (24) from p-liydroxyacetophenone. ... 

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