Amine oxides enamines

Other oxidative methods have recently been reported whereby amines yield enamines either as intermediates [130] or as isolatable chloranil [131], 2,3-dichloronaphtha-l,4-quinone [131], or 2,5-dichloro-3,6-dimethoxybenzo-quinone [132, 133] adducts. Benzoyl peroxide [131] and active manganese dioxide [134] have been reported as effective oxidizing agents in the reactions above. (See Eqs. 49, 50.)... 

Ab Initio MO calculations of a model complex Rh(PH3)2(NH3)(CH2=CHCH2NH2) were earned out to shed light to the detailed mechanism of Rh(l)-catalyzed isomerization of allylic amines to enamines.5 This study suggests that the square-planar [RhiPHjyNHjXCf CHCHjNHj) complex is transformed to [Rh(PH3)2(NH3)(( )-CH3CH=CHNH2)]+ via intramolecular oxidative addition of the C(l)-H bond to the Rh(I) center, giving a distorted-octahedral Rh(lll) hydride intermediate, followed by reductive elimination accompanied by allylic transposition. 

Many common reactions of aliphatic amines, ethers, and sulfides 1 involve initial addition of an electrophilic reagent utilizing the lone pair of electrons on the heteroatom salts, quaternary salts, coordination compounds, amine oxides, sulfoxides, and sulfones are formed in this way. Corresponding reactions are very rare (cf. Section 3.3.1.3) with pyrroles, furans, and thiophenes. These heterocycles react with electrophilic reagents at the carbon atoms 2, 3 rather than at the heteroatom. Vinyl ethers and enamines 4 show intermediate behavior, reacting frequently at the -carbon but sometimes at the heteroatom. 

The amine-oxide (316) reacts with trifluoroacetic anhydride in the manner depicted in Scheme 13. The iminium ion (317) has the properties of a Mannich reagent, and alkylates a second steroid molecule in the enamine form (318) to give the 2-methylene-3-ketone (31-9) after hydrolysis. The demethylated amine was formed at the same time. Different behaviour of the A -unsaturated amine oxide (320) results from participation of the olefinic bond in a novel type of Grob... 

Enamines can be obtained as the products of the Polonovski reaction of amine oxides and, in particular, by reaction of piperidine A -oxides with acetic anhydride. This is primarily due to the fact that when acetate is the counterion the intermediate iminium ions are labile and readily tautomerize. The formation of enamines during the Polonovski reaction is also favored by the presence of a base. In fact, enamines are often obtained in high yield from the reaction of an IV-oxide with trifluoroacetic anhydride in the presence of triethylamine or pyridine. Conversion of intermediate iminium ions, generated under modi-fred Polonovski conditions, to enamine products can also occur during hydrolytic work-up. 

Some other metal salts and other reagents which have been used to oxidize tertiary amines to enamines include palladiumfll) chloride copper(II) chloride , copperfi) chloride with oxygen , iodine, iodine pentafluoride , chlorine dioxide S permanganate ion , manganese dioxide , AT-bromosuccinimide , benzoyl peroxide , quinones and azodiformate . ... 

Cycloaddition of arynes to enamines gives aminobenzocyclobutenes, which undergo amine elimination or ring expansion on thermolysis of the amine oxide (Scheme 116). 

These findings were extended to a set of very useful cascade reactions by the MacMiUan group [111]. In a first series 1,4-hydride additions were combined with aminations, oxidations, or Mannich reactions (Scheme 4.30). The hydride transfer was catalyzed by imidazoHdinone 9, whereas subsequent functionalization was realized by enamine catalysis through the deployment of proline. Depending on the chirality of proline used, optically pure anti- or syu-configured products 84-86 were isolated. 

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). 

Typical nucleophiles known to react with coordinated alkenes are water, alcohols, carboxylic acids, ammonia, amines, enamines, and active methylene compounds 11.12]. The intramolecular version is particularly useful for syntheses of various heterocyclic compounds[l 3,14]. CO and aromatics also react with alkenes. The oxidation reactions of alkenes can be classified further based on these attacking species. Under certain conditions, especially in the presence of bases, the rr-alkene complex 4 is converted into the 7r-allylic complex 5. Various stoichiometric reactions of alkenes via 7r-allylic complex 5 are treated in Section 4. 

Thiirane is more bactericidal than oxirane, and derivatives of 2-mei captomethylthiirane inhibit tuberculosis. The following pharmacological uses have been reported for compounds derived from thiirane derivatives gold complexes of the adducts of diethylphosphine and thiirane (antiarthritic), adducts of thiiranes and malononitrile (antibacterial, blood vessel dilators, muscle relaxants, sedatives), thermolysis products of thiirane 1-oxides and adducts of thiirane 1-oxides with sulfenyl chlorides (antibacterial), adducts of 2,3-diarylthiirene 1,1-dioxides with ynamines (antibacterial, parasiticidal), adducts of 2,3-diarylthiirene 1,1-dioxides with enamines (antifertility), adducts of p-aminophenylacetic esters with thiirane (immunosuppressants), adducts of amines and thiiranes (radioprotective drugs). 

Enamines via Mercuric Acetate Oxidation of Tertiary Amines. 

The most versatile method for preparing enamines involves the condensation of aldehydes and ketones with secondary amines [Eq. (1)]. Mannich and Davidsen (/) discovered that the reaction of secondary amines with aldehydes in the presence of potassium carbonate and at temperatures near 0° gave enamines, while calcium oxide and elevated temperatures were required to cause a reaction between ketones and secondary amines, although usually in poor yield. The introduction by Herr and Heyl 2-4) of the removal of the water produced in the condensation by azeotropic distillation with benzene made possible the facile preparation of enamines from ketones and disubstituted aldehydes. 

The cyclic thioketone, 3-oxotctrahydrothiophene (11), gives a mixture of enamines (12,13) when caused to react with a secondary amine such as piperidine or pyrrolidine (31). The enamine mixture can be reduced to the 3-aminotetrahydrothiophene using formic acid or oxidized to the 3-amino-thiophene using diisopentylsulfide. 

The oxidation of amines by mercuric acetate is an old reaction (54) which up until recent years was employed primarily to modify alkaloid structures (55). A systemic study of the oxidizing action of mercuric acetate by Leonard and co-workers led to the development of a general method for the synthesis of enamines from cyclic tertiary amines. An observation made after a large number of compounds were oxidized, but which is worth noting at the onset, is that a tertiary hydrogen alpha to the nitrogen atom is removed preferentially to a secondary a-hydrogen. 

The preceding section described the preparation of enamines by mercuric acetate oxidation of tertiary amines. The initial product in these oxidations is the ternary iminium salt, which is converted to the enamine or mixture of enamines by reaetion with base. Thus iminium salts synthesized by methods other than the oxidation of tertiary amines or the protonation of enamines are potential enamine sources. 

The lithium- -propylamine reducing system has been found capable of reducing julolidine (113) to /d -tetrahydrojulolidine (114, 66% yield) and 1-methyl-1,2,3,4-tctrahydroquinoline to a mixture of enamines (87% yield), l-methyl-J -octahydroquinoline (115) and 1-methyl-al -octahydro-quinoline (116) 102). This route to enamines of bicyclic and tricyclic systems avoids hydroxylation, which occurs during mercuric acetate oxidation of certain bicyclic and tricyclic tertiary amines 62,85 see Section III.A). 

The previous sections have dealt with stable C=N-I- functionality in aromatic rings as simple salts. Another class of iminium salt reactions can be found where the iminium salt is only an intermediate. The purpose of this section is to point out these reactions even though they do not show any striking differences in their reactivity from stable iminium salts. Such intermediates arise from a-chloroamines (133-135), isomerization of oxazolidines (136), reduction of a-aminoketones by the Clemmensen method (137-139), reductive alkylation by the Leuckart-Wallach (140-141) or Clarke-Eschweiler reaction (142), mercuric acetate oxidation of amines (46,93), and in reactions such as ketene with enamines (143). 

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