Radicals addition to oximes

B. Free Radical Additions to Oximes, Oxime Ethers and Nitrones. 142... 

Free radical addition to oximes and oxime ethers emerged as a useful alternative to addition of organometallic reagents, particularly for intramolecular reactions. The most important advantage of free radical V5. organometallic addition is its tolerance for almost any functional group (with the exception of thiocarbonyl and iodoalkyl functions). 

Furthermore, we also performed kinetic studies for alkyl radical additions onto different types of C=N bonds such as imines and oxime ethers. The kinetic data are summarized in Figure S. Kinetic analysis of the intramolecular addition of alkyl radicals to C=N bonds provides several experimentally important results. First, alkyl radical additions to C=N bonds are much faster than the corresponding additions to C=C bonds, indicating that C=N bonds are much better radical acceptors than C=C bonds. Furthermore, 5-exo cyclization is faster than 6-exo cyclization. Second, the intramolecular additions of alkyl radicals to C=N bonds are essentially irreversible. Third, alkyl radical additions to oxime ethers and hydrazones are faster than alkyl radical additions to imines, suggesting the possibility of a dependence of the cyclization rate on the electron density at the carbon atom of the radical acceptor. 

Scheme 24 Alkyl radical addition to oxime ethers by Naito [15,16]...

The (TMS)3Si radical addition to terminal alkenes or alkynes, followed by radical cyclization to oxime ethers, were also studied (Reaction 50). The radical reactions proceeded effectively by the use of triethylborane as a radical initiator to provide the functionalized pyrrolidines via a carbon-carbon bond-forming process. Yields of 79 and 63% are obtained for oxime ethers connected with an olefin or propargyl group, respectively. 

The ZnEt2-initiated radical additions to glyoxylic384 and other374 oxime ethers, including those anchored to a polymer (e.g., 272), yielded valuable precursors for a-amino acids (Scheme 143). 

On the other hand, since oxime ethers were electrochemically more inert than ketones under the electroreduction conditions, the electroreductive intra- and inter-molecular coupling of ketones with oxime ethers proceeded via anion radicals in good yields (equations 5 and 6) °4i. Moreover, cobaloxime-mediated intramolecular radical addition onto oxime functions in the electrolysis media proceeded to afford the cyclized aminoethers (equation 7). ... 

Highly diastereoselective alkyl radical addition to Oppolzer s camphorsultam derivative (33) of oxime provides enantiomerically pure a-alkyl-a-amino acid derivative (34) at — 78 °C by the same method as shown in eq. 10.16. Moreover, enantioselective tandem radical 1,2-difunctionalization of cinnamamide (35) can be carried out with high stereoselectivity, using the chelation manner of the cinnamamide and a chiral bisoxazoline ligand on Mgl2, as shown in eq. 10.17. 

The C=N bond of simple imines possesses modest reactivity toward intermolecular radical additions, so such acceptors have rarely been exploited. To enhance their reactivity toward nucleophilic radicals, electron-withdrawing groups at the imine carbon have been effective, as demonstrated by Bertrand in radical additions to a-iminoesters prepared from chiral amines [25]. Also, more reactive oxime ethers have been exploited extensively for radical addition, mainly through the longstanding efforts of Naito [26]. In most cases, stereocontrol has been imparted through the substituents on the imino carbon chiral O-substituents on oximes for stereocontrol were ineffective, presumably due to poor rotamer control [27, 28]. 

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]. 

The quinoline formation from 2,4-dinitrophenyl oximes suggested to us the possibility of generating radical intermediates and prompted us to study the synthesis of cyclic imines by iminyl radical addition to an internal olefinic moiety as shown in Scheme 44. 

Scheme 22 Alkyl radical additions to phenylsulfonyl oxime ethers by Kim and Kim [ 14]...

Naito and co-workers investigated aqueous medium radical addition to glyoxylic oxime ether due to its good reactivity in organic solvents.9 Its noteworthy that triethylborane acts as a radical initiator and terminator to trap the intermediate alkyl radical (Scheme 7.6). 

Scheme 7.6 Alkyl radical addition to glyoxylic oxime initiated by Et3B and proposed mechanism.

Scheme 20. Naito s radical addition to glyoxylic oxime ether...

Diastereoselective radical additions to glyoxylic oxime ethers are well established however, only one recent report describes attempted enantioselective additions using chiral Lewis acids [26], It was found that bisoxazoline ligand 9 provided the best results as illustrated in Eq. (18) and Table 3. 

The Naito group has also prepared pyrrolidines [23] on solid phase by a combination of intermolecular radical addition to alkene 43 (Scheme 10) followed by intramolecular oxime ether cyclization to yield 44. These reactions proceeded sluggishly with triethylborane at room temperature, while the analogous solution-phase process was kinetically much faster. Radical additions to the phenylsulfonyl oxime ether 45 were reported by Jeon et al. [24]. Yields were better with primary and secondary alkyl iodides, and the tandem cyclization sequence with iodide 46 to afford bicyclic 47 was also accomplished, albeit in modest yield. 

Radicals are also produced by manipulation of the a-carboxy and amino groups. The former usually results in decarboxylation, with the products no longer being a-amino acids [61]. Aminyl radicals have been generated from sulfenamide precursors and exploited in cyclization reactions, as illustrated in Scheme 11 [62]. Radical additions to imines [63], oximes [64], isothiocyanates [65] and isocyanides [66] of a-... 

Treatment of the 1,6-anhydromannose derivative 67 as indicated in Scheme 14 gave the product 68 of radical addition to the oxime ether, and 68 was then convertible to the a-methylene-y-lactone 69, which can be considered as a potential intermediate in a synthesis of tetrodotoxin. Interestingly, the O-silylated form of 67 did not undergo cyclization satisfactorily. A number of related radical annulations were also reported (see Section 4 for one case). ... 

The key step in the total synthesis of e/ir-lycoricidine, recently accomplished by Keck and Wager [55] consisted of the thiy] radical addition to a triple bond of a suitable precursor followed by cyclization onto a pendant oxime moiety, as shown in Scheme 7. Then the alkoxyaminyl radical abstracts hydrogen from PhSH, when R=C02Me, or attacks intramolecularly the carbonyl moiety, when R = CHO. Following the former strategy, the target compound was obtained after two other transformations and in an overall yield of 11.1 % starting from lyxo.se, in 14 steps. 

Entries 20 to 23 involve additions to C=N double bonds in oxime ethers and hydrazones. These reactions result in installation of a nitrogen substituent on the newly formed rings. Entry 20 involves the addition of the triphenylstannyl radical to the terminal alkyne followed by cyclization of the resulting vinyl radical. The product can be proto-destannylated in good yield. The ring closure generates an anti relationship for the amino substituent, which is consistent with the TS shown below. 

Clerici and Porta reported that phenyl, acetyl and methyl radicals add to the Ca atom of the iminium ion, PhN+Me=CHMe, formed in situ by the titanium-catalyzed condensation of /V-methylanilinc with acetaldehyde to give PhNMeCHMePh, PhNMeCHMeAc, and PhNMeCHMe2 in 80% overall yield.83 Recently, Miyabe and co-workers studied the addition of various alkyl radicals to imine derivatives. Alkyl radicals generated from alkyl iodide and triethylborane were added to imine derivatives such as oxime ethers, hydrazones, and nitrones in an aqueous medium.84 The reaction also proceeds on solid support.85 A-sulfonylimines are also effective under such reaction conditions.86 Indium is also effective as the mediator (Eq. 11.49).87 A tandem radical addition-cyclization reaction of oxime ether and hydrazone was also developed (Eq. 11.50).88 Li and co-workers reported the synthesis of a-amino acid derivatives and amines via the addition of simple alkyl halides to imines and enamides mediated by zinc in water (Eq. 11.51).89 The zinc-mediated radical reaction of the hydrazone bearing a chiral camphorsultam provided the corresponding alkylated products with good diastereoselectivities that can be converted into enantiomerically pure a-amino acids (Eq. 11.52).90... 

Tandem processes mediated by triethylborane involving conjugate addition to enones followed by aldol reaction are reported (Scheme 52, Eq. 52a). More recently, a tandem process involving addition of an isopropyl radical to an o ,/3-unsaturated oxime ether afforded an azaenolate intermediate that reacts with benzaldehyde in the presence of trimethylaluminum. The aldol product cyclizes to afford an isopropyl substituted y-bulyroloaclonc in 61% overall yield (Scheme 52) [116]. In these reactions, triethylborane is acting as a chain transfer reagent that delivers a boron enolate or azaenolate necessary for the aldolization process. 

In qualitative terms, the rearrangement reaction is considerably more efficient for the oxime acetate 107b than for the oxime ether 107a. As a result, the photochemical reactivity of the oxime acetates 109 and 110 was probed. Irradiation of 109 for 3 hr, under the same conditions used for 107, affords the cyclopropane 111 (25%) as a 1 2 mixture of Z.E isomers. Likewise, DCA-sensitized irradiation of 110 for 1 hr yields the cyclopropane derivative 112 (16%) and the dihydroisoxazole 113 (18%). It is unclear at this point how 113 arises in the SET-sensitized reaction of 110. However, this cyclization process is similar to that observed in our studies of the DCA-sensitized reaction of the 7,8-unsaturated oximes 114, which affords the 5,6-dihydro-4//-l,2-oxazines 115 [68]. A possible mechanism to justify the formation of 113 could involve intramolecular electrophilic addition to the alkene unit in 116 of the oxygen from the oxime localized radical-cation, followed by transfer of an acyl cation to any of the radical-anions present in the reaction medium. 

Several functional groups in addition to carbon-carbon double and triple bonds can participate in radical cyclizations. Among these are oxime ethers, imines, and hydrazones. Cyclization at these functional groups leads to amino-substituted products. 

An alkyl group (primary, secondary, or tertiary) can be added to the oxime ether CHr=NOCH2Ph by treatment with the appropriate alkyl halide and an equimolar amount of bis(trimethylstannyl)benzopicolinate.483 This reaction, which is a free radical addition, is another way to extend a chain by one carbon. 

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