Oxidation to amines

Primary amino groups are oxidized stepwise by ozone to hydroxylamine, nitroso, and nitro (54,58) tertiary amines are oxidized to amine oxides. 

Imanaka—heterogenization of Rh complexes. In 1991, Imanaka and coworkers124 reported the heterogenization of Rh complexes by binding them to aminated polymers. As discussed previously, these findings led to fruitful research by Ford, Pardey, and others. The isolated polymer-bound Rh carbonyl anion complex was found to be reusable for reactions such as water-gas shift and reduction of nitro compounds. The polymer-bound Rh complexes were characterized by infrared spectroscopy. Water-gas shift activity (80 mol H2 per mol Rh6(CO)i6 in 24 hours) was recorded using the Rh complexes at 100 °C with 0.92 atm of CO, 2.16 ml H20, 0.05 mmol Rh6(CO)16, aminated polystyrene, 5.0 mmol of N, 5.56 ml ethoxyethanol and reduction of nitro-compounds (e.g., aliphatic nitro compounds to nitriles, oximes to nitriles, hydroxylamines to nitriles, and N-oxides to amines) occurred at 40 °C. 

Cyclophosphamide (6.31) is a nitrogen mustard used for cancer treatment (Scheme 6.9). In the body, cyclophosphamide is oxidized to aminal 6.32. Compound 6.32 opens and loses acrolein to form phosphoramide mustard (6.33). Structure 6.33 is a strong bis-electrophile and reacts readily with nucleophiles. In DNA, the nucleophile tends to be N7 of guanine, which is oriented outward into the major groove (Figure 6.6). By reacting twice, 6.33 crosslinks DNA either within the same strand (intrastrand) or across the double helix (interstrand).16... 

Aliphatic tertiary amines can be oxidized to A/-oxides using 35% mjm aqueous hydrogen peroxide alone,303 typically in water at 1.1 1 molar ratio of oxidant to amine for 4-5 h at 60-65 °C. This method is employed worldwide for the production of 25 kilo-tons per annum of fatty amine oxides which are invariably used as surfactants304 in personal care products, and as thickener compounds in hypochlorite household bleaches. JV-Methylmorpholine oxide... 

NaH, dimethylformamide (DMF), CH3I], undergoes electrophilic nitration (89), Friedel-Crafts acylation (90), and alkylation (91) at the C-9 position. Although attempts to effeet a Baeyer-Villiger oxidation of ketone 90 were successful, the route was laborious since oxidation to amine oxide 92 preceded oxidation of the methyl ketone 90. However, a Dakin reaction of aldehyde 91 gave 9-hydroxy-6-methylellipticine (93) in excellent yield. It remains to be seen if this methodology can be extended to an N-unsubstituted ellipticine. 

Homer and Hoffmann" reported use of triphenylphosphine for the deoxygcnution of azoxy compounds to uzo compounds, of peroxides to ethers, of nitrones to Schiff bases, and of aliphatic amine oxides to amines. The lalier reiicliun was done in nfliKina iieatic anld and under these contillloni the N-oxides of pyridine and quinoline... 

With the recognition of the extensive occurrence of amine oxides as alkaloids in the plant there have been developed differential isolation procedures, to separate these from the amines, and reduction procedures, applied to crude extracts, to convert all the amine oxides to amines. For qualitative detection of amine oxides, the red or reddish brown coloration that these compounds give with acetic anhydride serves as a useful test (150). The problem of the separation of the natmnlly occurring amines from the amine oxides has been attacked in different ways. In the first instance of isolation (56-56c), it was found that both trachelanthamine and its, -oxide could be extracted from an aqueous solution by dichloroethane. Sequences of organic extractants such as ether followed by chloroform (116) and chloroform followed by butanol... 

Kulanthaivel P, Barbuch RJ, Davidson RS, Yi P, Rener GA, Mattiuz EL, Hadden CE, Goodwin LA, Ehlhardt WJ. Selective reduction of A-oxides to amines application to drug metabolism. Drug Metab Dispos 2004 32 966-972. 

Examples of such consecutive competing reactions are chlorination, nitration of hydrocarbons, or the addition of alkene oxides (e.g., ethylene oxide) to amines or alcohols. If the mixing is fast enough, so that the reacting fluid is homogenous before the reaction takes place, the maximum yield of the desired intermediate A3 will be controlled by the ratio of k2/ky Let us suppose irreversible second order reactions, so the following relations describe the transformation rates of the involved reactants. 

A halogen atom directly attached to a benzene ring is usually unreactive, unless it is activated by the nature and position of certain other substituent groups. It has been show n by Ullmann, however, that halogen atoms normally of low reactivity will condense with aromatic amines in the presence of an alkali carbonate (to absorb the hydrogen halide formed) and a trace of copper powder or oxide to act as a catalyst. This reaction, known as the Ullmant Condensation, is frequently used to prepare substituted diphenylamines it is exemplified... 

Alkyl groups attached to aromatic rings are oxidized more readily than the ring in alkaline media. Complete oxidation to benzoic acids usually occurs with nonspecific oxidants such as KMnO, but activated tertiary carbon atoms can be oxidized to the corresponding alcohols (R. Stewart, 1965 D. Arndt, 1975). With mercury(ll) acetate, allyiic and benzylic oxidations are aJso possible. It is most widely used in the mild dehydrogenation of tertiary amines to give, enamines or heteroarenes (M. Shamma, 1970 H. Arzoumanian. 1971 A. Friedrich, 1975). 

Reactions with Organic Compounds. Tetrafluoroethylene and OF2 react spontaneously to form C2F and COF2. Ethylene and OF2 may react explosively, but under controlled conditions monofluoroethane and 1,2-difluoroethane can be recovered (33). Benzene is oxidized to quinone and hydroquinone by OF2. Methanol and ethanol are oxidized at room temperature (4). Organic amines are extensively degraded by OF2 at room temperature, but primary aHphatic amines in a fluorocarbon solvent at —42°C are smoothly oxidized to the corresponding nitroso compounds (34). 

NO formation occurs by a complex reaction network of over 100 free-radical reactions, and is highly dependent on the form of nitrogen in the waste. Nitro-compounds form NO2 first, and then NO, approaching equiHbrium from the oxidized side. Amines form cyano intermediates on their way to NO, approaching equiHbrium from the reduced side. Using air as the oxidant, NO also forms from N2 and O2. This last is known as thermal NO. ... 

HydrometallurgicalProcesses. HydrometaHurgical refining also is used to extract nickel from sulfide ores. Sulfide concentrates can be leached with ammonia (qv) to dissolve the nickel, copper, and cobalt sulfides as amines. The solution is heated to precipitate copper, and the nickel and cobalt solution is oxidized to sulfate and reduced, using hydrogen at a high temperature and pressure to precipitate the nickel and cobalt. The nickel is deposited as a 99 wt % pure powder. 

Commercially, pure ozonides generally are not isolated or handled because of the explosive nature of lower molecular weight species. Ozonides can be hydrolyzed or reduced (eg, by Zn/CH COOH) to aldehydes and/or ketones. Hydrolysis of the cycHc bisperoxide (8) gives similar products. Catalytic (Pt/excess H2) or hydride (eg, LiAlH reduction of (7) provides alcohols. Oxidation (O2, H2O2, peracids) leads to ketones and/or carboxyUc acids. Ozonides also can be catalyticaHy converted to amines by NH and H2. Reaction with an alcohol and anhydrous HCl gives carboxyUc esters. 

The zwitterion (6) can react with protic solvents to produce a variety of products. Reaction with water yields a transient hydroperoxy alcohol (10) that can dehydrate to a carboxyUc acid or spHt out H2O2 to form a carbonyl compound (aldehyde or ketone, R2CO). In alcohoHc media, the product is an isolable hydroperoxy ether (11) that can be hydrolyzed or reduced (with (CH O) or (CH2)2S) to a carbonyl compound. Reductive amination of (11) over Raney nickel produces amides and amines (64). Reaction of the zwitterion with a carboxyUc acid to form a hydroperoxy ester (12) is commercially important because it can be oxidized to other acids, RCOOH and R COOH. Reaction of zwitterion with HCN produces a-hydroxy nitriles that can be hydrolyzed to a-hydroxy carboxyUc acids. Carboxylates are obtained with H2O2/OH (65). The zwitterion can be reduced during the course of the reaction by tetracyanoethylene to produce its epoxide (66). 

Reduction. Just as aromatic amine oxides are resistant to the foregoing decomposition reactions, they are more resistant than ahphatic amine oxides to reduction. Ahphatic amine oxides are readily reduced to tertiary amines by sulfurous acid at room temperature in contrast, few aromatic amine oxides can be reduced under these conditions. The ahphatic amine oxides can also be reduced by catalytic hydrogenation (27), with 2inc in acid, or with staimous chloride (28). For the aromatic amine oxides, catalytic hydrogenation with Raney nickel is a fairly general means of deoxygenation (29). Iron in acetic acid (30), phosphoms trichloride (31), and titanium trichloride (32) are also widely used systems for deoxygenation of aromatic amine oxides. 

All lation. Alkylating agents such as diaLkyl sulfates and alkyl hahdes react with ahphatic amine oxides to form trialkylalkoxyammonium quaternaries. For example (33), methyl iodide reacts with trimethyl amine oxide to form trimethylmethoxyammonium iodide... 

Primary and secondary amines are oxidized to the respective hydroxyl amines, and further oxidation to the nitro compound occurs ia the case of primary amines. 

Ethoxylation and Propoxylation. Ethylene oxide [75-21-8] or propylene oxide [75-56-9] add readily to primary fatty amines to form bis(2-hydroxyethyl) or bis(2-hydroxypropyl) tertiary amines secondary amines also react with ethylene or propylene oxide to form 2-hydroxyalkyl tertiary amines (1,3,7,33—36). The initial addition is completed at approximately 170°C. Additional ethylene or propylene oxide can be added by using a basic catalyst, usually sodium or potassium hydroxide. 

Oxidation. Aromatic amines can undergo a variety of oxidation reactions, depending on the oxidizing agent and the reaction conditions. For example, oxidation of aniline can lead to formation of phenyUiydroxylamine, nitrosobenzene, nitrobenzene, azobenzene, azoxybenzene or -benzoquinone. Oxidation was of great importance in the early stages of the development of aniline and the manufacture of synthetic dyes, such as aniline black and Perkin s mauve. 

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