Deoxygenation groups

As another example of nitrene formation, the reaction of o-nitrostilbene (96) with CO in the presence of SnCU affords 2-phenylindole (97). The reaction is explained by nitrene formation by deoxygenation of the nitro group with CO, followed by the addition of the nitrene to alkene. Similarly, the 2//-indazole derivative 99 was prepared by reductive cyclization of the A-(2-nitrobenzyli-dene)amine 98[89]. 

Nucleophilic substitution occurs in positions a and y to the N-oxide group. In nearly all these reactions deoxygenation occurs giving the substituted heterocychc amine. 

Treatment of pyridazine 1-oxides with phosphorus oxychloride results in a-chlorination with respect to the N-oxide group, with simultaneous deoxygenation. When the a-position is blocked, substitution occurs at the y-position. 3-Methoxypyridazine 1-oxide, for example, is converted into 6-chloro-3-methoxypyridazine and 3,6-dimethylpyridazine 1-oxide into 4-chloro-3,6-dimethylpyridazine. 

Nitropyridazines are reduced catalytically either over platinum, Raney nickel or palladium-charcoal catalyst. When an N-oxide function is present, palladium-charcoal in neutral solution is used in order to obtain the corresponding amino N-oxide. On the other hand, when hydrogenation is carried out in aqueous or alcoholic hydrochloric acid and palladium-charcoal or Raney nickel are used for the reduction of the nitro group, deoxygenation of the N- oxide takes place simultaneously. Halonitropyridazines and their N- oxides are reduced, dehalogenated and deoxygenated to aminopyridazines or to aminopyridazine N- oxides under analogous conditions. 

In a study of the deoxygenation of carbonyl compounds by atomic carbon, Dewar and coworkers (8UA2802) presented experimental and theoretical evidence that the carbonyl group can react with carbon atoms to form a carbenaoxirane. 

Nucleophilic displacement of the butoxy group in 2-butoxy-3//-azepine (1) by the use of excess secondary amine is preferred by some workers64 to the photolysis or thermolysis of aryl azides, or the deoxygenation of nitro- or nitrosoarenes in amine solution, as a preparative route to Ar,Ar-dialkyl-3//-azcpin-2-amines, e.g. 2,... 

A direct attack of nucleophiles on the sulfur atom of the sulfone or sulfoxide group in acyclic or large-ring sulfones and sulfoxides is rather rare, or unknown, excluding metal hydride reductions and/or reductive deoxygenations. The situation is completely different in the three-membered ring systems. 

Because quinoxalines are often converted into their N-oxides in order to facilitate other reactions, subsequent removal of the oxide entity without untoward effects is quite important. The choice of a reagent for such deoxygenation is frequently governed by the type(s) of passenger group present direct comparisons of several methods have bee presented. " The following classified examples illustrate most of the possibilities available. 

The success of dibekacin prompted worldwide attention to the removal of selected OH groups in aminoglycoside antibiotics susceptible to modification by resistant bacteria, and the chemical deoxygenation procedure of D. H. R. Barton was found particularly useful. 

Quebrachitol was converted into iL-c/j/roinositol (105). Exhaustive O-isopropylidenation of 105 with 2,2-dimethoxypropane, selective removal of the 3,4-0-protective group, and preferential 3-0-benzylation gave compound 106. Oxidation of 106 with dimethyl sulfoxide-oxalyl chloride provided the inosose 107. Wittig reaction of 107 with methyl(triphenyl)phos-phonium bromide and butyllithium, and subsequent hydroboration and oxidation furnished compound 108. A series of reactions, namely, protection of the primary hydroxyl group, 0-debenzylation, formation of A-methyl dithiocarbonate, deoxygenation with tributyltin hydride, and removal of the protective groups, converted 108 into 7. 

Paulsen and his coworkers first synthesized (-f-)-203 from L-quebrachitol (286) by a 21-step reaction as follows. The di-O-isopropylidene derivative was oxidized to the ketone (287), and then epoxidized with dimethyl sulfox-onium-methylide to give 288, which was subjected to benzoylation, mesyla-tion, and demethylation, followed by benzylation, to afford 289. Introduction of unsaturation was accomplished by epoxidation of 289 with sodium methoxide to 290 and 291, and deoxygenation to 292. The azido group was introduced with azobis(dicarboxylate) to give 293, which was hydrogeno-lyzed, followed by deprotection to afford 203. 

Through extensive screening of compounds, " " " it was revealed that this enzyme accepts a very wide range of substrates. In addition to phosphorylated aldose, which are the native substrate, non-phosphorylated aldose, simple aliphatic, aromatic, heterocyclic and functionalized aldehydes, even with an increased hydropho-bicity, work as substrates. The stereochemical course has been elucidated in Fig. 18. The hydroxyl group on the 2-position of the aldehyde is very important and 2-deoxygenated aldehydes were rather weak substrates. The substrates with d-configuration at the 2-position have a stronger affinity to TKase than L-form. 

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