Carbon-nitrogen bonds oximes

The Beckmann rearrangement is one of the typical reactions of oxime derivatives and the N-substituted nitrilium ion intermediates have been widely exploited as synthetic intermediates for the preparation of nitrogen-containing heterocycles, " while few examples have been reported for the nucleophilic substitution on the sp nitrogen atom of oximes. Even though, in some of them, carbon-nitrogen bond formation is realized, these reactions have not been well generalized as synthetic tools. ... 

Reduction of compounds already containing a carbon-nitrogen bond such as oximes, Schiff bases, nitro-compounds, etc. 

For nylon 6, caprolactam is made from the oxime by acid-catalyzed Beckman rearrangement. As shown by reaction 8.4.2, heating caprolactam under nitrogen breaks the carbon-nitrogen bond and gives the polymer. 

The oxime ethers (such as outlined in Scheme 6) are attractive candidates for mechanistic studies concerning the E,Z-photoisomerization of imines (vide infra) because the presence of the alkoxyl group drastically reduces the rates of thermal interconversion (K x 10 at 60 C) and allows mechanistic studies to be carried out at ambient temperatures.Padwa and Albrecht studied photochemical ,Z-isomeriza-tion regarding the carbon-nitrogen bond of O-methyl oxime ethers in some detaU. They found that upon direct irradiation of the O-methyl oximes of acetophenone, a photostationary state Z E ratio of... 

Carbon—nitrogen double bonds in imines, hydrazones, oximes, nitrones, azines, and substituted diazomethanes can be cleaved, yielding mainly ketones, aldehydes and/or carboxyHc acids. Ozonation of acetylene gives primarily glyoxal. With substituted compounds, carboxyHc acids and dicarbonyl compounds are obtained for instance, stearoHc acid yields mainly azelaic acid, and a smaH amount of 9,10-diketostearic acid. 

Compounds containing carbon-nitrogen double bonds can be hydrolyzed to the corresponding aldehydes or ketones. For imines (W = R or H) the hydrolysis is easy and can be carried out with water. When W = H, the imine is seldom stable enough for isolation, and hydrolysis usually occurs in situ, without isolation. The hydrolysis of Schiff bases (W = Ar) is more difficult and requires acid or basic catalysis. Oximes (W = OH), arylhydrazones (W = NHAr), and, most easily, semicarbazones (W = NHCONH2) can also be hydrolyzed. Often a reactive aldehyde (e.g., formaldehyde) is added to combine with the liberated amine. 

Several functional groups containing carbon-nitrogen double bonds can participate in radical cyclizations. Among these are oxime ethers, imines, and hydrazones.337 Hydrazones and oximes are somewhat more reactive than imines, evidently because the adjacent substituents can stabilize the radical center at nitrogen.338 Cyclization at these functional groups leads to amino- substituted products. 

Fry and Newberg 1,2> examined the electrochemical reduction of nor-camphor oxime (109) and camphor oxime (110) to the corresponding amines. The results of this study are shown in Table 3. It is clear from a comparison of these data with those in Table 2 that the electrochemical reduction of oximes 109 and 110 takes a very different stereochemical course from reduction of the corresponding anils 103 and 104. Reduction of oximes apparently proceeds under kinetic control, affords products corresponding to protonation at carbon from the less hindered side of the carbon-nitrogen double bond, and affords the less stable epimeric amine in each case. It is not evident why the stereochemistry of reduction of anils and oximes should differ, however. 

Titanium silicate molecular sieves not only catalyze the oxidation of C=C double bonds but can be successfully employed for the oxidative cleavage of carbon-nitrogen double bonds as well. Tosylhydrazones and imines are oxidized to their corresponding carbonyl compounds (243) (Scheme 19). Similarly, oximes can be cleaved to their corresponding carbonyl compounds (165). The conversion of cyclic dienes into hydroxyl ketones or lactones is a novel reaction reported by Kumar et al. (165) (Scheme 20). Thus, when cyclopentadienes, 1,3-cyclohexadiene, or furan is treated with aqueous H202 in acetone at reflux temperatures for 6 h in the presence of TS-1, the corresponding hydroxyl ketone or lactone is obtained in moderate to good yields (208). 

Owing to the relative rigidity of the carbon-nitrogen double bond, oximes can exist in two discrete geometrically isomeric forms the E or anti isomer anti-E-217) and the (Z) or syn isomer (syn-Z-217) (equation 70). In solid state, both oximes show high configurational stability and discrete existence. In solution, equilibrium between both isomers is rapidly established, favouring the thermodynamically most stable isomer " ... 

Dehydrofluorination of lV,0-bis(tnfluoromethyl)hydroxylanune with potassium fluoride gives an excellent yield of a perfluorinated oxime ether [25] with a carbon-nitrogen double bond (equation 23)... 

Triazolines resulting from diazomethane addition to the carbon-nitrogen double bond in oximes decompose rapidly even at 20°C to give N-alkoxyaziridines.361,362... 

In the base-catalysed dehydration for oxime formation a significant development of the carbon-nitrogen double bond in the TS is assumed. 

Unlike many other type of radical addition reactions, the product is most often an alkyl-cobalt(III) species capable of further manipulation. These product Co—C bonds have been converted in good yields to carbon-oxygen (alcohol, acetate), carbon-nitrogen (oxime, amine), carbon-halogen, carbon-sulfur (sulfide, sulfinic acid) and carbon-selenium bonds (equations 179 and 180)354. Exceptions to this rule are the intermolecular additions to electron-deficient olefins, in which the putative organocobalt(III) species eliminates to form an a,/ -unsaturated carbonyl compound or styrene353 or is reduced (under electrochemical conditions) to the alkane (equation 181)355. 

In the case of the carbon-nitrogen double bond, the reaction of isomerization can occur via rotation about the double bond, and by nitrogen inversion (XLVII). The latter process as a rule is strongly favored over rotation, resulting in a lowered barrier of overall isomerization as compared to ethylenes. For many imines (XLVII, c = H), this barrier is in the range 20-30 kcal/mol. Electronegative substituents on the nitrogen atom increase stability toward inversion, as evidenced by the relative stability of oximes (XLVII, c = OH) and hydrazones (XLVII, c = NRR ) [56]. 

Oximes, hydrazones, semicarbazones, diazines and carbodiimides all undergo reactions involving addition to a carbon-nitrogen double bond (A, D], but these reactions are of limited value, with the exception of the reaction with ketoximes. This last reaction, with an excess of Grignard at elevated temperatures, is a useful route to aziridines, (4), although yields are rarely high. In some cases, reduction of the intermediate azirine (2) leads to an alternative aziridine (5). 

Imines and related compounds containing a carbon-nitrogen double bond C=N (hydrazones, acylhydrazones, oximes) present the very attractive feature of being double dynamic entities capable of undergoing both ... 

Recently, radical species have attracted much attention as useful intermediates for carbon-carbon bond formations. By contrast, in organic synthesis, radicals centered on heteroatoms have not been widely utilized for construction of molecular skeletons with carbon-heteroatom bond formation. In this section we will discuss the generation of alkylideneaminyl radicals, conventionally called iminyl radicals from oxime derivatives by electron transfer reactions. AU -lideneaminyl radicals thus created are utilized for making nitrogen-containing heterocycles. 

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