Ketoximes, oxidation

Although 1,2-benzisothiazoles can be prepared by the oxidation method, they are also available by cyclization of o-mercaptobenzaldoximes and ketoximes with polyphosphoric acid (72AHC 14)43, 73JCS(P1)356, 77JCS(P2)1114). This method has been improved by the use of S-t- butyl analogues, which do not suffer from the instability of the free thiols (79SST 5)345). 

The photochemical cyclisation of p.y-unsaturated ketoximes to 2-isoxazolines, e.g., 16—>17, has been reported <95RTC514>. 2-Isoxazolines are obtained from alkenes and primary nitroalkanes in the presence of ammonium cerium nitrate and formic acid <95MI399>. Treatment of certain 1,3-diketones with a nitrating mixture generates acyl nitrile oxides, which can be trapped in situ as dipolar cycloadducts (see Scheme 3) <96SC3401>. 

On treatment of trialkylsilyl nitronates 1043 with MeLi, LiBr, or BuLi in THF the resulting nitrile oxide intermediates 1044 afford, in dilute THF solution (R=Me) the ketoximes 1045 in ca 50-60% yield, whereas in concentrated THF solution the O-silylated hydroxamic acids 1046 are obtained as major products [144] (Scheme 7.35). Analogously, the silyl nitronate 1047 reacts with the 2,3,4,6-tetra-O-acetyl-/ -D-glucopyranosyl thiol/triethylamine mixture to afford, via the thiohydroxi-mate 1048, in high yield, a mixture of oximes 1049 which are intermediates in the synthesis of glucosinolate [145] (Scheme 7.35). 

Anhydrous peroxytrifluoroacetic acid is not easy to handle, but the procedure has recently been revised.121 Namely, reaction of urea-hydrogen peroxide complex (UHP) with tri-fluoroacetic anhydride in acetonitrile at 0 °C gives solutions of peroxytrifluoroacetic acid, which oxidize aldoximes to nitroalkanes in good yields (Eqs. 2.58 and 2.59). Ketoximes fail to react under these conditions, the parent ketone being recovered. 

The conversion of oximes to nitroalkanes has been achieved by employing an Mo(IV) oxodiperoxo complex as oxidant in acetonitrile. Both aldoximes and ketoximes are converted into the corresponding nitroalkanes (Eqs. 2.61 and 2.62),123 representing a complementary synthetic route to the use of the UHP method. 

The constituent of paint, 2-nitropropane, exhibiting genotoxicity and hepatocarcinogeni-city was oxidized by liver microsomes forming nitric oxide, which was identified as a ferrous NO complex [61]. Clement et al. [62] concluded that superoxide may participate in the microsomal oxidation of /Y-hydroxyguanidincs, which produced nitric oxide, urea, and the cyanamide derivative. Caro et al. [63] suggested that the oxidation of ketoxime acetoxime to nitric oxide by microsomes enriched with P-450 isoforms might be mediated by hydroxyl or hydroxyl-like radicals. 

For example, the reaction of nitronates (123) with a zinc copper pair in ethanol followed by treatment of the intermediate with aqueous ammonium chloride a to give an equilibrium mixture of ketoximes (124) and their cyclic esters 125. Heating of this mixture b affords pyocoles (126). Successive treatment of nitronates (123) with boron trifluoride etherate and water c affords 1,4-diketones (127). Catalytic hydrogenation of acyl nitronates (123) over platinum dioxide d or 5% rhodium on aluminum oxide e gives a-hydroxypyrrolidines (128) or pyrrolidines 129, respectively. Finally, smooth dehydration of a-hydroxypyrrolidines (128) into pyrrolines (130f) can be performed. 

Closure of the oxadiazole ring is still achieved through cycloaddition between pyridine iV-oxides and isocyanates, affording adducts such as 142 (Scheme 38) <1995T6451>. Nonaromatic imine fV-oxides exhibited similar reactivities, since azasugar-derived fV-oxides as a mixture of 143 and 144 underwent cycloaddition reactions in the presence of phenyl isocyanate or trichloroacetonitrile. Compounds 145 and 146 (Scheme 39) were obtained from the aldoxime W-oxide 143 two other regioisomeric heterocycles arose from the ketoxime derivative 144 <1996T4467>. 

The pKi, values of a series of para- and meffl-substituted benzaldoximes and phenyl methyl ketoximes, ArCR=NOH (R=H, Me), have been measured in DMSO. The aldoximes exhibit pK. = 20.05 + 3.21ap. The homolytic bond dissociation energy of the O-H bond has been estimated as 88.3 (aldoximes) and 89.2kcal mol" (ketoximes) by relating the pK to the oxidation potential of the conjugate base (i.e. ox for ArCR=NO- ArCR=NO ). 

Yields are frequently moderate for Scholl reactions. Aldoximes are not usually compatible with these harsh reaction conditions and are very sensitive to factors such as temperature and reaction time. Consequently, oxidation to the corresponding carboxylic acid is a major side-reaction. However, both the ketoxime (51) and the aldoxime (53) are reported to give good yields of the corresponding m-dinitro compounds, (52) and (54) respectively, on treatment with absolute nitric acid in methylene chloride followed by hydrogen peroxide. 

Some recent advances have been reported in oxime oxidation, including the in situ generation of peroxytrifluoroacetic acid from the reaction of urea hydrogen peroxide complex with TFAA in acetonitrile at 0 °C This method gives good yields of nitroalkanes from aldoximes but fails with ketoximes. 

Peroxyacetic acid generated in situ from sodium perborate and glacial acetic acid has been used for oxime to nitro group conversion. Peroxyimidic acid generated from acetonitrile and hydrogen peroxide has found similar use. An Mo(IV) peroxy complex has been reported for the oxidation of both ketoximes and aldoximes. 

This process of synthesis of ketoximes as described by Scheme 12 is termed ammox-imation. The source of NH2OH is the oxidation of NH3 to NO (or NO2) followed by reduction with H2 or SO2. The reactants were passed over a Pt catalyst at low pressures and high temperatures (>800 °C). 

Hydrogenated isoxazole derivatives were obtained by single electron transfer (SET) cyclization of /9,y-unsaturated oximes , by thermal [4- -2] cycloaddition of aldox-imes or ketoximes to conventional dienophiles or isomerization/cyclization of an ortho halogeno or nitro-substituted amidoximes. Preparation of 1,4-disubstituted 3-hydroximino-2-nitro-l-butenes and their oxidative cyclization to 4-nitroisoxazoles are reported " . Synthesis of fluorine-containing substituted isoxazolidines as well as isoxazoles by ultrasonic methods has been also described. 

Usually, electrochemical oxidative hydrolysis of ketoximes affords the corresponding ketones. Hence, 2-octanone (equation 13) and acetophenone were obtained from the corresponding ketoximes in 90% and 97% yields, respectively. However, camphor oxime was transformed into the ring-cleaved nitrile (equation 14). ... 

By analogy with the biogenesis of oximes via oxidation of amino acids or biogenic amines, the biosynthetic pathway for insertion of the ketoxime function into the antibiotic, nocardicin A (18), was shown to be dependent on the oxidation of the corresponding primary amine precursor of 18 by cytochrome PTSO ". Similarly, the formation of the ketoxime bond of verongamine (17) is attributed to the oxidation of a primary amine precursor . 

Oxidative deoximation/ Ketoximes revert to ketones by reaction with H,0, in an alkaline medium (75 95° yield, five examples). 

Di-f-butyliminoxyl, [(CH3)3C]2C=NO (1). The blue radical is obtained on oxidation of di-t-butyl ketoxime with CAN in CH3OH. It is extracted with pentane or hexane and stored at -15°. 

---