Oximes reaction with lead

Oximes react with lead tetraacetate (one-half equivalent) in acetic acid at 70° (1 hr.) to give the corresponding carbonyl compound in 60-90% yield. The reaction can even be applied to unsaturated oximes if an equivalent amount of anhydrous... 

An unactivated methyl group can be functionalized by the cyclopalladation of oximes. The equatorial methyl of geminal methyls in steroids or hexapyr-anosides is selectively aceto.xylated by the reaction of the palladation complex 523 of the 3-oxime with lead tetraacetate[467,468]. 

The reaction with oximes of cyclic ketones leads to formation of lactams (e.g. 6 — 7) by ring enlargement ... 

The pharmacological versatility of this general substitution strategy is further illustrated by diazonium coupling of 14 with 2-nitrobenzenediazonium chloride to produce biarylal-dehyde 18. Formation of the oxime with hydroxylamine is followed by dehydration to the nitrile. Reaction with anhydrous methanolic hydrogen chloride leads to imino ether and addition-elimination of ammonia leads to the antidepressant amid-ine, nitrafudam (20). ... 

In many cases, the yields of these products are high. However, the use of /V-silylated triazoles as nucleophiles or the use of cyclic nitroso acetals (475) substituted at the C-3 atom leads to a noticeable decrease in the yield of the oximes. Therefore, steric hindrance in nitroso acetals and a decrease in nucleophilicity of A-centered nucleophiles result in an increase in the contribution of side reactions. It should be emphasized that C -nucleophiles, such as anions of nitro compounds, are not involved in coupling reactions with cyclic nitroso acetals (475). However, the products, which formally correspond to the C,C-coupling mechanism, can be prepared by the nucleophilic substitution of chlorine in compound (476 d) by a Sa/2 mechanism (Scheme 3.254, product (483c), the yield was 79%). 

Axenrod and co-workers reported a synthesis of TNAZ (18) starting from 3-amino-l,2-propanediol (28). Treatment of (28) with two equivalents of p-toluenesulfonyl chloride in the presence of pyridine yields the ditosylate (29), which on further protection as a TBS derivative, followed by treatment with lithium hydride in THF, induces ring closure to the azetidine (31) in excellent yield. Removal of the TBS protecting group from (31) with acetic acid at elevated temperature is followed by oxidation of the alcohol (32) to the ketone (33). Treatment of the ketone (33) with hydroxylamine hydrochloride in aqueous sodium acetate yields the oxime (34). The synthesis of TNAZ (18) is completed on treatment of the oxime (34) with pure nitric acid in methylene chloride, a reaction leading to oxidation-nitration of the oxime group to em-dinitro functionality and nitrolysis of the A-tosyl bond. This synthesis provides TNAZ in yields of 17-21 % over the seven steps. 

Conversion of a ketone to a highly substituted imine interestingly leads to a compound which shows analgesic activity, anidoxime (197). Phenyl 2-di-ethylaminoethyl ketone is converted to its oxime (196) in the usual way, and this is converted to anidoxime by reaction with p-methoxyphenylisocyanate. 

Synthesis of l-hydroxy-3-oxyimidazolines from a-hydroxylaminooximes has been reviewed " . Therefore, in the present work it will be described very briefly. In general, the reaction of oximes 136 with aldehydes, ketone or triethyl orthoformate leads to imidazolines 137 or 138, respectively (equation 60). 

In some cases 0-substituted oximes reacted with azomethine ylides. Thus, reaction of 0-substituted oxime (NC)2C=NOTs 139 with azomethine yhde derived from aziridine 140 afforded imidazoline 141 in 44% yield (equation 61). Addition of lithium derivative of silylated alkyne to oxime ethers 142 leads to 4-ethynyl-Af-hydroxy-2-imidazolines 143 in 49-72% yields (equation 62) . 

The reaction of a-halo ketone oximes 204 with isocyanides leads to formation of 5-aminoisoxazole derivatives 205. The reaction involves formation of nitrosoalkenes as intermediates (equation 89) ". ... 

Bicyclic derivatives of furazan A-oxide are prepared by nitrile oxide dimerization reaction. Dioxime 272 (R, R = Me) undergoes cyclization to the corresponding 4,4-tetramethylperhydrocycloocta[c]furazan A-oxide 273 (84% yield) by treatment with NaOCl/HaO/CHaCla at 0°C and then refuxing in toluene (equation 117). However, in the cases of sterically less hindered oximes 272 (R = H, Me R = H) only complex mixtures of oligomerization and cyclization products could be obtained ". Interestingly, the reaction of pyridyl oxime -274 with TsCl afforded 1,2,5-oxadiazole 275 as single product (equation 118). On the other hand, the reaction of Z-isomer of oxime 274 leads only to 0-tosylated oxime. ... 

A free radical cyclization of oxime ethers tethered to an aldehyde has been used in the synthesis of azepine derivatives . For example, oxime ether 389 is cyclized to azepine 390 by reaction with Sml2 in HMPA and f-BuOH at —78°C (equation 170) . Similar free radical cyclization of oxime ethers can be carried out also in the presence of Bu3SnH/AIBN in benzene . Oxime 0-methyl ether 391 underwent thermal cyclization in refluxing o-dichlorobenzene (ODCB) leading to the mixture of two products 392 and 393 in ratio 69 31 in overall yield of 91% (equation 171) °. Rearrangement of oxime 0-tosylates in the presence of piperidine also leads to azepine ring formation . ... 

One exception is the reaction of acetone oxime with divinyl ketone in the presence of an equimolar amount of zinc(II) bromide (162). Acetone oxime reacts with divinyl ketone on heating in THE at reflux, leading to both conjugate addition and nitrone cycloaddition, producing a 5 1 mixture of regioisomers with 8-oxa-l-azabicyclo[3.2.1]octan-4-one as the major isomer (Scheme 11.42). On the other hand, in the presence of an equimolar amount of zinc(II) bromide, 7-oxa-l-azabicyclo[3.2.1]octan-4-one is the major isomer (97 3) in a total yield of 97%, indicating that the Lewis acid has controlled the regioselectivity of the second step, namely, the cycloaddition. 

Complexes involving oxime ligands display a variety of reactivity modes that lead to unusual types of chemical compounds. As far as the oxime chemistry of platinum is concerned, these complexes are involved in facile deprotonation of the OH group with formation of oximato complexes, reduction of Pt(IV) species, Pt(II)-assisted reactions with coordinated allene," alkylation by ketones, oxime-ligand-supported stabilization of Pt(III)—Pt(III) compounds, oxidative conversion into rare nitrosoalkane platinum(II) species, and coupling with organocyanamides. ... 

A benzofuran ring replaces one of the benzene rings of the biphenyl moiety present in many of the sartans in the rather more complex drug saprisartan (80-10). It is of note, further, that the acidic proton is provided in this case by a trifluorosulfo-namide instead of the more common tetrazole ring. Construction of the imidazole fragment begins by nitrosation of the (3-ketoester (79-1) by means of sodium nitrite in acid to afford the oxime (79-2). Reaction with acetyl chloride leads to the ester (79-3). Reaction of this last intermediate with the iminoether from propionitrile then affords the imidazole (79-4). 

The product (15-2) from aldol condensation of meto-nitrobenzaldehyde with the dimethyl acetal from ethyl 4-formylacetoacetate (15-1) provides the starting material for a dihydropyridine in which one of the methyl groups is replaced by a nitrile. Reaction of (15-2) with the eneamine from isopropyl acetoacetate gives the corresponding dihydropyridine hydrolysis of the acetal function with aqueous acid affords the aldehyde (15-3). That function is then converted to its oxime (15-4) by reaction with hydroxylamine. Treatment of that intermediate with hot acetic acid leads the oxime to dehydrate to a nitrile. There is this obtained nilvadipine (15-5) [16]. 

Yet another piperidine-based antipsychotic agent replaces the butyrophenone or diarylpropyl function found in earlier compounds by a benzopyrimidine group. The synthesis starts by the conversion of the carboxylic acid in piperidine (22-1) to its acid chloride. Reaction with 1,3-difluorobenzene (22-2) in the presence of aluminum chloride affords the acylated product (22-3). Reaction with hydroxylamine leads to the corresponding oxime (22-4). Treatment of that derivative with a base... 

The dibasic side chain at position 7 can be alternatively provided by a substituted amino alkyl pyrrolidine. Preparation of that diamine in chiral form starts with the extension of the ester function in pyrrolidone (46-1) by aldol condensation with ethyl acetate (46-2). Acid hydrolysis of the (3-ketoester leads to the free acid that then decarboxylates to form an acetyl group (46-3). The carbonyl group is next converted to an amine by sequential reaction with hydroxylamine to form the oxime, followed by catalytic hydrogenation. The desired isomer (46-4) is then separated... 

Upon reaction with nitrous acid, indole produces a complex mixture of products. In addition to 3-oximino-3H -indole (16), which is the stable tautomeric form of 3-nitrosoindole (17), dimeric products of the type (18) and (19) are also formed. In contrast, (16) appears to be the sole product of the nitrosation of indole with amyl nitrite and sodium ethoxide (72HC(25-2)537). Studies of the nitrosation of pyrrole are somewhat indecisive. The mononitrosopyrrole, obtained from the reaction of pyrrole with nitrous acid, has not been fully characterized, but there is some evidence that nitrosation of pyrrole with amyl nitrite and sodium ethoxide leads to the sodium salt of the 3-nitroso derivative. However, upon the addition of acid, the product rearranges to give the oxime of 3-formylisoxazole (20) (B-77MI30502). 

The same products were also obtained by treatment of quinuclidin-3-one (2) with hydrazoic acid under Schmidt reaction conditions175 here the process gives mainly the monocyclic amide (147). Reaction of quinuclidin-3-one oxime (103) with arylsulfonyl chlorides in alkali leads to fragmentation and formation of iV-substituted 3-cyano-piperidines.179,177... 

With 1,2-dibromoethane (run 4) under comparable conditions (run 2), somewhat poorer results are achieved with the same total yield (about 30%), the crude product contains nearly 40% of the starting oxime. As in the reaction with free acetylene (see Section II.C.l), the substitution of KOH by NaOH and LiOH (run 5,6) makes the process completely selective, but leads to a sharp drop in the yield of products and in the oxime conversion. 

The interactions of compounds containing the oxime group with coordinated organonitriles are very important in template syntheses [384,413-416], These reactions take place as a nucleophilic addition and lead to the formation of complexes with unusual iminoacyl ligands. The iminoacylation reaction was studied in detail for various oximes and organonitriles, coordinated to PtCl4 [384,413-416]. Thus, the template transformation (3.192) of the discussed type in case of the oximes 744 takes place in acetonitrile or chloroform and yields complexes of the type 745 [413a] ... 

The participation of nitrilium salts has also been postulated42 in the Schmidt reaction and in some Beckmann rearrangements when concentrated sulfuric acid is employed. Hill43 has demonstrated recently that some Beckmann rearrangements carried out in a concentrated sulfuric acid medium are Ritter-type reactions in which the nitrile formed in situ from the oxime combines with a carbonium ion to yield a nitrilium salt, which, when diluted with water, leads to the N-alkylamide. 

The synthesis of FQ (Fig. 20) is simple and quite economical, which renders FQ attractive for the development of an antimalarial drug intended for use in areas, concerned by malaria, that are mostly overlaying with low-income countries. FQ was obtained starting from the commercially available AQV-dimethyl-1-ferrocenylmethanamine. The ferrocenic aldehyde results from a C-C bond formation, a two-step sequence involving metallation with tert/o-butyllithium and a reaction with DMF. This step has been previously studied and the 1,2 orientation of the two substituents of the cyclopentadienyl has been unambiguously established [125], The aldehyde is converted to the corresponding oxime, which is then reduced to the primary amine. The SNat reaction between the amine and 4,7-dichloroquinoline leads to the desired FQ [121]. 

Heating o-nitrosophenols with hydroxylamine is reported to give furazans, naphtho[l,2-c]furazan (95) being formed from both l-nitroso-2-naphthol and 2-nitroso-l-naphthol, presumably by oximation of the tautomeric o-naphthoquinone monooximes and subsequent dehydration. Compound (95) has also been prepared by oxidation, using alkaline ferri-cyanide or hypochlorite, of l-amino-2-nitroso- and 2-amino-l-nitroso-naphthalene. This latter approach is suitable for heterocyclic fused furazans thus 4,6-diamino-5-nitrosopyrimidine is converted into the furazanopyrimidine (96) by oxidation with lead tetraacetate (71JOC3211). In a similar reaction alkaline hypochlorite oxidizes o-nitrosoacetaniiide to benzofurazan in quantitative yield. 

Examples include the synthesis of 3-amino-l,2,4-oxadiazoles starting from 3-acylamino-5-methyl-l,2,4-oxadiazole <2002H811> and 2-aryl-l,2,3-triazoles from l,2,4-oxadiazole-3-ketone arylhydrazones <1999T12885, 2006JOC5616>. Oximes, hydrazones, formamidines, and thioureas of the furazan series also undergo base-catalyzed mononuclear rearrangements <2004RCB1121>. Nucleophilic attack at N(3) takes place in the benzofuroxan series. For example, reaction with secondary amines leads to o-nitroarylhydrazines (Scheme 55). 

The reaction of oxime 385 with polyphosphoric acid results in ring expansion via Beckmann rearrangement leading to the fused 1,4-benzothiazepine derivative 386 (Scheme 207) <1997JHC921, CHEC-III(13.09.10.2)286>. 

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