Oximes addition reactions

Azirines (three-membered cyclic imines) are related to aziridines by a single redox step, and these reagents can therefore function as precursors to aziridines by way of addition reactions. The addition of carbon nucleophiles has been known for some time [52], but has recently undergone a renaissance, attracting the interest of several research groups. The cyclization of 2-(0-tosyl)oximino carbonyl compounds - the Neber reaction [53] - is the oldest known azirine synthesis, and asymmetric variants have been reported. Zwanenburg et ah, for example, prepared nonracemic chiral azirines from oximes of 3-ketoesters, using cinchona alkaloids as catalysts (Scheme 4.37) [54]. 

The addition of allylboronates 1 to the chiral oxime 2 results in the formation of a hydroxyl-amine. This is a general method for the subsequent reductive generation of primary homoallyl-amines, but with poor diastereoselectivity in the case of 3 and 4. A diastereomeric ratio of 90 10 is achieved in the addition reaction, using the chiral allylboronate 59 (double stcrcodifferenti-ation). 

In carbonyl addition reactions, a commonly occurring and important mechanistic step is the transfer of a proton from one site to another in a reactive intermediate (proton switch). If the proton switch occurs sufficiently rapidly compared with the rate of collapse of the intermediate to reactants, the overall reaction may be facilitated by trapping of the unstable intermediate by the proton switch (Jencks, 1976). For example, in the formation of oximes from the reaction of benzaldehyde with O-methylhydroxylamine shown in (87H89) (Sayer and Jencks, 1973 Rosenberg et al., 1974), the first unstable intermediate (It) on the reaction pathway is converted by a proton switch (88) to the intermediate (I2) which has less tendency than It to... 

The electrophile-induced cyclization of heteroatom nucleophiles onto an adjacent alkene function is a common strategy in heterocycle synthesis (319,320) and has been extended to electrophile-assisted nitrone generation (Scheme 1.62). The formation of a cyclic cationic species 296 from the reaction of an electrophile (E ), such as a halogen, with an alkene is well known and can be used to N-alkylate an oxime and so generate a nitrone (297). Thus, electrophile-promoted oxime-alkene reactions can occur at room temperature rather than under thermolysis as is common with 1,3-APT reactions. The induction of the addition of oximes to alkenes has been performed in an intramolecular sense with A-bromosuccinimide (NBS) (321-323), A-iodosuccinimide (NIS) (321), h (321,322), and ICl (321) for subsequent cycloaddition reactions of the cyclic nitrones with alkenes and alkynes. 

Hanessian s group investigated the addition reactions of oximes using bis(oxazo-line) ligand As shown in Figure 9.55b, reaction of the a-oximino ester... 

This procedure is based on the formation of the electophile NO+, which can react with an ellagic acid residue (4.2) at two sites, either via a substitution reaction which results in 4.3, or an addition reaction that results in the nitrosyl dienone 4.4. These compounds can decay to form the quinine oxime 4.5, which under alkaline conditions forms the red product 4.6. When related compounds, such as gallic acid, phloroglucinol, hydroxycinnamic acids, and phenol are subjected to this assay, a yellow-brown product is formed, which does not interfere with the spectrophotometric detection of ellagic acid. 

A new reaction of iV-acyl thiazolidinethione enolates with enolizable aldoxime ethers has been reported to give 2-(thiazolidine-2-thione)-l-azetines 608 with excellent diastereoselectivity (Equation 235) <2003JA3690>. The absence of either a methoxy or a carbonyl group in the 1-azetines indicated a complex mechanism rather than a simple addition reaction. The formation of azetines has been rationalized by combination of the oxime and TiCh to give a highly electrophilic trichlorotitanium iminium intermediate 609, which adds onto enolate 610 to form intermediate 611, which cyclizes to azetidines 612 (Scheme 81). An irreversible elimination of bis-trichlorotitanium oxide provides the ultimate driving force to produce azetines. 

The Co-derived system constitutes a distinctly less efficient HAT reagent than CpCr(CO)3H and can also be used in kinetically less favored radical addition reactions, such as additions to oximes, and even dimerizations of benzylic radicals as shown in Scheme 10 [31, 32]. 

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. 

Although there is ample evidence for nucleophilic additions to benzyne la> and some other unstable angle strained cycloalkyne intermediates 15,27,31,205 207), only a few addition reactions to isolable angle strained cycloalkynes are known which can be classified as nucleophilic. Hydroxylamine and hydrazine add to (31) to yield the corresponding oxime and hydrazone, resp. 208). 

In the classic carbohydrate chemistry addition reactions of carbonyl groups served as valuable tools for sturctural studies of carbohydrates. For example, hydroxyl amine, hydrazine, and phenyl hydrazine react with carbonyl groups to yield oximes and hydrazones. In the presence of an excess... 

There are many examples of acid catalyzed carbonyl addition reactions, such as formation of hydrates (R2C(OH)2), hemiacetals, hemiketals, cyanohydrins, bisulfite compounds, azomethines, oximes, hydrazones, etc. These important reactions are discussed in Vol. 11. 

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