C=N double bond

Sulfonium ylides may be added to C N double bonds to yield aziridines in a formal [1 -t-2]-cycloaddition. Alkyl azides are decomposed upon heating or irradiating to yield ni-trenes, which may also undergo [ 1 + 2 -cycloaddition reactions to yield highly strained hetero-cycles (A.G. Hortmann, 1972). 

Isocyanates are Hquids or soHds which are highly reactive and undergo addition reactions across the C=N double bond of the NCO group. Reactions with alcohols, carboxyUc acids, and amines have been widely exploited ia developiag a variety of commercial products. Cycloaddition reactions involving both the C=N and the C=0 double bond of the NCO group have been extensively studied and used for product development (1 9). 

Among unsaturated C—N—N three-membered rings only the 3H-diazirines (3) are known. IH-Diazirines with a C=N double bond were never obtained. Diazirines with one or two alkyl groups at carbon were prepared in many cases, aryldiazirines only in some cases. An important role is played by difluorodiazirine as well as by diazirines containing chlorine or bromine (9). 

The alkaloids cotamine (259), hydrastinine (261), and berberinal (260), each possessing a grouping formed by interaction of an aldehyde with a secondary amino group in their molecule, are unusual. The Grignard reaction of free base 166 does not occur as readily as that of the corresponding salt 167. Both reactions lead to the alkylated product 168. For example, only 50% of hydrastinine reacts and 50% is regenerated, whereas hydrastinine hydrochloride reacts almost quantitatively (261). The salt undoubtedly contains a C=N double bond. In the case of the free base, the presence of a C=N double bond was not proven, and the reaction probably occurs by direct cleavage of the C—OH bond. 

It is likely that initially the open-chain adducts 353 and 354 are formed by the addition of an amino group either to the carbonyl function or to the triple bond, whereupon these intermediates close up to the azepines 355 and their bis-imine tautomers 356. In the H NMR spectra, the methylene protons of 356 are at 2.85-2.97 ppm, whereas the methyl protons are fixed at 2.20-2.27 ppm. The IR spectra show absorption bands corresponding to the aromatic ring (1600 cm ) and to the diazepine cycle C=N double bonds (1580 cm ). However, there are no bands of... 

The formation of a stable imino-enole tautomer 358 is due to the conjugation of the C=C and C=N double bonds with the aromatic ring and hydroxyl group. The enaminoketone tautomer 357 is present in a negligible amount. 

A new method for the synthesis of 1,2,5-thiadiazoline 5,5-dioxides 231 was achieved by reacting activated aryl nucleophiles to the C=N double bond of the corresponding thiadiazoles 230 in the presence of AlClj as a catalyst at room temperature (00MI4). The yields of 4-aryl-derivatives ranged from 38 to 92%. 

Normal reactions are found again for systems containing C=N double bonds. An unstable triazoline is probably an intermediate product in the reaction of pteridin-7-one (117)to give a mixture of the 8-methyl (118) and 6,8-dimethyl derivatives (119). C-Methylation also occurs in the case of quinoxalin-2-one. ... 

Because of the high polarity of the C=N double bonds, cyanuric chloride (120, R= Cl) is comparable with a carboxylic acid chloride. This explains its smooth reaction with diazomethane to yield dichloro-(diazomcthyl)-l,3,5-triazine (121, R = The analogous com-... 

The isomer lowest in energy is predicted to be the 2,5-dihydro-1,2,4-triazine 198g. The most stable structures always show two C=N double bonds. Moreover, in polar solvents, 198h should also be a dominant species [00PCCP2187]. The valence and Rydberg excited states of 1,2,3-triazine have been studied by multireference methods (MRD-CI) and the results are compared with experimental spectra [98CP39]. 

However, when 3,5-diphenyl-4//-pyrazol-4-one, a reagent that undergoes Diels- Alder reactions with inverse-electron demand, is used, addition of the 2,4-diene part of oxepin to one of the two C-N double bonds of the pyrazolone is observed to give 4.232... 

H-Azirine-2-carboxylates such as 57 (Scheme 3.19) are a special class of imines that undergo additions to their C=N double bonds to give aziridine-2-carboxylates... 

The addition of organometallic reagents to the C —N double bond of imines 1 provides an attractive route to amines 21 2. However, due to the poor electrophilici ty of imines, this method is often plagued by competitive reactions ... 

Reductive Dimerization2 5,6 can be competitive with the addition of Grignard reagents to the C —N double bond of nonenolizable imines, especially with increasing size and branching of the carbanion,... 

Nevertheless, there are promising strategies which may help to overcome these problems, for example, the use of less basic organometallics and/or the activation of the C-N double bond by Lewis acids. Therefore, it is not particularly surprising that the number of publications dealing with the stereochemical aspects of these reactions increases continuously. 

These results may be rationalized by assuming a chelation model. The nucleophile preferentially attacks the less hindered side of the C — N double bond as depicted. 

The stereochemical course of the reaction may be explained by assuming a fivc-membered chelate with the nucleophile attacking the less hindered side of the C—N double bond (alkoxy-mediated S -attack)18. This model is supported by the fact that (he stereoselectivity of the reaction clearly diminishes if smaller nucleophiles, e.g., ethylmagnesium bromide, are employed. The use of valinol methyl ether effects slightly better results19. 

Thiazolinc 2 proves to be inert to organometallic attack. However, addition of organolithium and Grignard reagents to the C —N double bond of 2 can easily be achieved by previous activation with boron trifluoridc, providing /r[Pg.696]

The synthesis of alkoxy amines 2 by addition of organometallic reagents to the C-N double bond of oxime ethers 1 is plagued by the propensity for proton abstraction a. to the C-N double bond, the lability of the N-O bond and the poor electrophilicity of the oxime ethers. Therefore, frequently no products, undesired products or complex mixtures are obtained. The result depends on the substrate, organometallic reagent, solvent, temperature and additives1 6. 

The diastereoselectivity of the reaction may be rationalized by assuming a chelation model, which has been developed in the addition of Grignard reagents to enantiomerically pure a-keto acetals7,8. Cerium metal is fixed by chelation between the N-atom, the methoxy O-atom and one of the acetal O-atoms leading to a rigid structure in the transition state of the reaction (see below). Hence, nucleophilic attack from the Si-face of the C-N double bond is favored4. 

Deacetylanisomycin (4) is synthesized using L-tartaric acid (1) as a precursor in 12% overall yield16. The key step is the diastereoselective addition of (4-methoxybenzyl)magnesium chloride to the C — N double bond of nitrone 2 at 0°C in the presence of 1 equivalent of ethylmagncsium-bromide diethyl ether complex in dichloromethane. This procedure affords a chromatograph-ically separable mixture of the hydroxylamines 3 a and 3 b in a diastereomeric ratio [(2R,35,4R)/ (25,35,47 )] 70 30 and 60% yield from 2. 

The addition of electron-rich enamines2-5 to preformed imines and imine derivatives so far has scarcely been investigated6 -15 compared to the addition of enolatcs (see Section 1.4.3., refs 16 and 17 and literature cited therein). Most of the known examples refer to iminium salts because they are more reactive than the corresponding iinines due to their highly polarized C-N double bond (see Section 1.4.1.6., ref 16 and literature cited therein). 

The diastereodifferentiating effect of the galactosylamine template in these Strecker reactions is rationalized in terms of a preferred conformation 5 of the Schiff bases which is stabilized by a (7i-double bond into the carbohydrate ring. This conformation is supported by a strong NOE in the H-NMR spectrum between the anomeric and the iminc proton. 

The diastereofacial selectivity of this asymmetric [3C+2S] process is explained following a model similar to that described in Sect. 2.6.4.4 for the reaction of chiral alkenylcarbene complexes and 1,3-dienes. Thus, the proposed mechanism that explains the stereochemistry observed assumes a [4+2] cycloaddition reaction between the chromadiene system and the C=N double bond of the imine. The necessary s-cis conformation of the complex makes the imine... 

Primary or secondary aliphatic nitro compounds can be hydrolyzed, respectively, to aldehydes or ketones, by treatment of their conjugate bases with sulfuric acid. This is called the Nef reaction Tertiary aliphatic nitro compounds do not give the reaction because they cannot be converted to their conjugate bases. Like 16-2, this reaction involves hydrolysis of a C=N double bond. A possible mechanism is" ... 

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