Oxidation tertiary amine

Industrial specifications for aHphatic tertiary amine oxides generally requite an amine oxide content of 20—50%. These products may contain as much as 5% unreacted amine, although normally less than 2% is present. Residual hydrogen peroxide content is usually less than 0.5%. The most common solvent systems employed are water and aqueous isopropyl alcohol, although some amine oxides are available ia aoapolar solveats. Specificatioas for iadividual products are available from the producers. 

This mechanism is the same as that of 19-23 the products differ only because tertiary amine oxides cannot be further oxidized. The mechanism with other peroxyacids is probably the same. Racemic (3-hydroxy tertiary amines have been resolved by oxidizing them with t-BuOOH and a chiral catalyst one enantiomer reacts faster than the other.This kinetic resolution gives products with enantiomeric excesses of > 90%. 

The reaction that is perhaps of the greatest synthetic utility—because it proceeds at relatively low temperatures—is the Cope reaction of tertiary amine oxides, e.g. (82) ... 

FIGURE 5.9 Reduction of tertiary amine oxides to tertiary amines. 

The reaction of tertiary amine oxides with nitrous acid has also been shown to produce N-nitroso compounds. The mechanism for the amine oxides is similar to that for the tertiary amines (26). 

Tertiary amine oxides and hydroxy la mines are also reduced by cytochromes P-450. Hydroxylamines, as well as being reduced by cytochromes P-450, are also reduced by a flavoprotein, which is part of a system, which requires NADH and includes NADH cytochrome b5 reductase and cytochrome b5. Quinones, such as the anticancer drug adriamycin (doxorubicin) and menadione, can undergo one-electron reduction catalyzed by NADPH cytochrome P-450 reductase. The semiquinone product may be oxidized back to the quinone with the concomitant production of superoxide anion radical, giving rise to redox cycling and potential cytotoxicity. This underlies the cardiac toxicity of adriamycin (see chap. 6). 

Tertiary amine oxides can be converted into TV-hydroxy secondary amines provided that one of the TV-substituents can be selectively eliminated. This procedure has been applied to the synthesis of secondary A-hydroxy-a-amino acids 34 from the corresponding secondary a-amino acids using the /V-cyanoethyl group for transient protection of the secondary amine (Scheme 10) J40l More recently, direct oxidation with 2,2-dimethyldioxirane of a primary amine has been described for H-L-Val-OMe (82% yield) and H-L-Phe-OMe (54% yield))13 The reaction proceeds smoothly without epimerization, but no experimental details have been reported. 

Tertiary amine oxides can be used instead of iodosylbenzene for the epoxidation of alkenes in the presence of Fe(TPP)Cl.500 p-Cyano-N,IV-dimethylaniline IV-oxide (p-CN-DMANO) has... 

Inclusion in the reaction of a cooxidant serves to return the osmium to the osmium tetroxide level of oxidation and allows for the use of osmium in catalytic amounts. Various cooxidants have been used for this purpose historically, the application of sodium or potassium chlorate in this regard was first reported by Hofmann [7]. Milas and co-workers [8,9] introduced the use of hydrogen peroxide in f-butyl alcohol as an alternative to the metal chlorates. Although catalytic cis dihydroxylation by using perchlorates or hydrogen peroxide usually gives good yields of diols, it is difficult to avoid overoxidation, which with some types of olefins becomes a serious limitation to the method. Superior cooxidants that minimize overoxidation are alkaline t-butylhydroperoxide, introduced by Sharpless and Akashi [10], and tertiary amine oxides such as A - rn e t h y I rn o r p h o I i n e - A - o x i d e (NMO), introduced by VanRheenen, Kelly, and Cha (the Upjohn process) [11], A new, important addition to this list of cooxidants is potassium ferricyanide, introduced by Minato, Yamamoto, and Tsuji in 1990 [12]. 

N-oxides are always present as cooxidation impurities in tertiary amine oxidation, due to the accumulation of hydrogen peroxide during autoxidation. 

Osmium tetroxide (0s04, sometimes called osmic acid) reacts with alkenes in a concerted step to form a cyclic osmate ester. Oxidizing agents such as hydrogen peroxide (H202) or tertiary amine oxides (R3N+—O-) are used to hydrolyze the osmate ester and reoxidize osmium to osmium tetroxide. The regenerated osmium tetroxide catalyst continues to hydroxylate more molecules of the alkene. 

A variation of the Hofmann elimination, where a tertiary amine oxide eliminates to an alkene with a hydroxylamine serving as the leaving group, (p. 907)... 

It is possible to speed up aliphatic tertiary amine oxidation by adding tungstate or molybdate catalysts.334 However, for oxidation of aromatic and particularly heterocyclic tertiary nitrogen, a stronger system than hydrogen peroxide alone is required. iV-Oxidation of heterocycles is of pivotal importance in industrial chemical synthesis.335 Catalysed systems have been applied and these are dominated by metal peroxo systems based on molybdenum or tungsten. For example, quinoxaline and pyrazine may be oxidized to mono- or... 

Sigmatropic Rearrangements of Tertiary Amine Oxides (The Meisenheimer Rearrangement)... 

The thermal rearrangement of tertiary amine oxides, the Meisenheimer rearrangement, generates O, A,A-trisubstituted hydroxylamines. 

Tertiary amine oxides with three different substituents exist as stable enantiomers8. Pure enantiomers were obtained by resolution. Asymmetric oxidation of tertiary amines usually gave amine oxides with low enantioselectivity8. Oxidation of Ar-(/f)-2-butcnyl-Ar-methyl-4-toluidine... 

Deoxygenation of Nitrones, Nitrile Oxides and Tertiary Amine Oxides... 

Methods of deoxygenation of nitrones (28), nitrile oxides (29), heteroaromatic N-oxides (30) and tertiary amine oxides (31) are described in this section. There are some reagents, such as trialkyl phosphites, which can deoxygenate compounds of all these types as well as those in the preceding section, whereas others are more limited in scope. Oae and coworkers have outlined three distinct mechanistic types of deoxygenation process, which are illustrated in Scheme 17. Clearly, a mechanism of type C will not apply to tertiary amine oxides (31) on the other hand, these compounds are more easily deoxygenated than heteroaromatic N-oxides, such as (30), by some reagents because the aromatic N-oxides are inherently more stable. 

The following reaction mechanism was ruled out by the authors cited [4 + 2] cycloaddition of the diene with the nitrone to give tertiary amine oxide, 7-21, which then thermally rearranges to the product. (Thermal rearrangement of a tertiary amine oxide to an alkylated hydroxylamine is called a Meisenheimer rearrangement.)... 

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