Nitronates bonding

Reductive Cross-Coupling of Nitrones Recently, reductive coupling of nitrones with various cyclic and acyclic ketones has been carried out electrochem-ically with a tin electrode in 2-propanol (527-529). The reaction mechanism is supposed to include the initial formation of a ketyl radical anion (294), resulting from a single electron transfer (SET) process, with its successive addition to the C=N nitrone bond (Scheme 2.112) (Table 2.9). 

Nitroparaffins and HBF react with alkynes through conjugate addition of a proton and the nitronate ion at the triple bond as illustrated by nitromethane and 5-decyne (53). 

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. 

The chlorination of 3,5-dimethylisoxazole gave the 3,4-dichloro-4-isoxazoline (489) (77MIP41602). Additional 2-substituted 4-isoxazolines were prepared by the addition of nitrones to triple bonds (76AP1014, 77H(8)387, 70CB3196, 67AG(E)709, 69CB2346), as shown by the conversion of (490) into (491) (76AP1014). 

Rearrangement involving cleavage of the C—O bond is also observed with the phenyl isocyanate adduct (59). In place of an O-acylated nitrone its product (60) of acyl migration is isolated (67JPR(36)86). 

Like isomerization of oxaziridines to nitrones, acid hydrolysis of oxaziridines proceeds with conservation of the N—O bond. Both reactions are related mechanistically and are... 

Formal addition products of 1,3-dipoles are compiled in a recent review (79AHC(24)63). Examples include addition to a nitrone forming a six-membered ring, to an enamine forming a pyrazolidine ring, and to the C=0 bond of diphenylcyclopropenone. 

The UV and IR spectra eliminate structures with a CN double bond. The isomerism of nitrones and oxaziranes thus cannot be a result of CIS or traris arrangement of substituents about a double bond. The carbon atoms of an oxazirane are still at the oxidation level of the carbonyl compound used in its syntheses. By acid hydrolysis, for example, 2-terf-butyl-3-phenyloxazirane (9) can be split into benzaldehyde and tert-butylhydroxylamine fEq. (8)]. ... 

Recently the synthetic method involving formation of the 1—5 and 3—4 bonds has been extended to the preparation of the completely hydrogenated system of A -substituted isoxazolidines (42). This interesting reaction results from 1,3-dipolar addition of nitrones (41) to olefins. " ... 

Nitrones are a rather polarized 1,3-dipoles so that the transition structure of their cydoaddition reactions to alkenes activated by an electron-withdrawing substituent would involve some asynchronous nature with respect to the newly forming bonds, especially so in the Lewis acid-catalyzed reactions. Therefore, the transition structures for the catalyzed nitrone cydoaddition reactions were estimated on the basis of ab-initio calculations using the 3-21G basis set. A model reaction indudes the interaction between CH2=NH(0) and acrolein in the presence or absence of BH3 as an acid catalyst (Scheme 7.30). Both the catalyzed and uncatalyzed reactions have only one transition state in each case, indicating that the reactions are both concerted. However, the synchronous nature between the newly forming 01-C5 and C3-C4 bonds in the transition structure TS-J of the catalyzed reaction is rather different from that in the uncatalyzed reaction TS-K. For example, the bond lengths and bond orders in the uncatalyzed reaction are 1.93 A and 0.37 for the 01-C5 bond and 2.47 A and 0.19 for the C3-C4 bond, while those in... 

Treatment of 2- 5//-dibenz[i>,/]azepin-5-yl acetaldehyde (16), prepared in 68% yield by /V-alkylation of 5/7-dibenz[A,/]azepine with bromoacetaldehyde diethyl acetal followed by acid hydrolysis, with methyl hydroxylamine yields the isolable nitrone 17, which in refluxing toluene undergoes intramolecular 1,3-dipolar cycloaddition at the CIO —Cl 1 alkene bond to give 2,3,3a, 12b-tetrahydro-2-methyl-3,8-methano-8//-dibenz[i>,/]isoxazolo[4,5-r/]azepine (18).235... 

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. 

In order to overcome the poor electrophilicity ofimines, nitrones arc used as partners for reaction with iron acyl enolates 428. Benzaldehyde phenylnitrone (5) reacts rapidly with the aluminum-based enolate at —78 C to give a crude /J-hydroxyamino iron acyl 6 (68% yield). Treatment with aqueous titanium trichloride in tetrahydrofuran at room temperature causes a selective reduction of the N—O bond and affords the /1-amino iron acyl 7 with inverse configuration compared to the addition ofimines (99% yield d.r. 11 23). 

With the proviso that the substrate not contain a, reactive carbon-carbon double bond, the present ozonolysis procedure7 appears to provide a convenient and efficient method for carrying out the desired transformation. As can be seen in Table I, both primary and secondary nitronates undergo the reaction. If a primary nitronate is to be used,... 

Intramolecular nitrone cycloadditions often require higher temperatures as nitrones react more sluggishly with alkenes than do nitrile oxides and the products contain a substituent on nitrogen which may not be desirable. Conspicuously absent among various nitrones employed earlier have been NH nitrones, which are tautomers of the more stable oximes. However, Grigg et al. [58 a] and Padwa and Norman [58b] have demonstrated that under certain conditions oximes can undergo addition to electron deficient olefins as Michael acceptors, followed by cycloadditions to multiple bonds. We found that intramolecular oxime-olefin cycloaddition (lOOC) can occur thermally via an H-nitrone and lead to stereospecific introduction of two or more stereocenters. This is an excellent procedure for the stereoselective introduction of amino alcohol functionality via N-0 bond cleavage. 

A somewhat unusual sequence to generate azepanones 80 involved the intramolecular addition of hydroxylamines to alkynes 76 to form cyclic nitrones 77. A vinyl magnesium bromide addition at low temperatures and a reduction with TiCls followed by N-Boc protection led to the azepane 78. Double bond bromination and subsequent RUO4 oxidation gave the lactam 79. Several further steps allowed the generation of the lactam structure 80 proposed for d,/-aca-cialactam, but the spectral data of the synthetic material differed from that of the natural product (Scheme 16)] [23 a, b]. 

This route has been widely exploited because of the availability of a-amino azomethine compoimds from natural (S)-a-amino acids, through the corresponding a-amino aldehydes, which are configurationally stable provided that the amino function is suitably protected. Moreover, some a-amino acids are available with the R configuration and a number of enzymatic and chemical transformations have been described for the preparation of optically active unnatural a-amino acids. Overall, the route suffers from the additional steps required for protection/deprotection of the amino function and, in the case of hydrazones and nitrones, cleavage of the N - N or N - O bond. 

The nitrone (64) does indeed add to the less "indered of the two double bonds in diene (65). 

The addition of mesityl nitrile oxide to stable derivatives of a germanethi-one21 and a germaneselone22 is closely related to the addition of nitrones. The reaction is regioselective again, with formation of the germanium-oxygen bond. 

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