Amines iminium salts

The formation of 88 is postulated to be occurring by the nucleophilic attack of a hydride ion (47), abstracted from the secondary amine, on the a-carbon atom of the iminium salt (89). The resulting carbonium ion (90) then loses a proton to give the imine (91), which could not be separated because of its instability (4H). In the case of 2-methyIhexamethylenimine, however, the corresponding dehydro compound /l -2-methylazacyclo-heptene (92) was isolated. The hydride addition to the iminium ion occurs from the less hindered exo side. 

The reduction was studied in more detail by Cook and Schulz (52). They demonstrated conclusively that reduction of iminium salts by secondary amines is possible as illustrated in Eqs. (7) and (8). The oxidation... 

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. 

Ternary iminium complex salts can be prepared by direct combination of an aldehyde or ketone with a secondary amine complex salt (95). An adaptation of this procedure employing the perchlorate salts of secondary amines provides a simple method for the preparation of the readily crystallized and nonhydroscopic ternary iminium perchlorates (96), Eq. (10). 

For purposes of characterization of enamines the perchlorate salts are preferred, as they crystallize well, and the perchlorate anion has no tendency to add to the iminium cation. Other salts, including hexachlorostannates (13), hexachloroantimonates (13), chlorides, bromides, tetraphenylborates, and nitrates, have also been used. Recently a method for the preparation of iminium salts directly from aldehydes or ketones and the amine perchlorate has been reported (16). 

The close agreement of the three methods supports the contention that protonation at low temperatures first occurs at nitrogen and is followed by a proton shift to give the iminium salt (M). The rate of this rearrangement is dependent on temperature, the nature of the amine, and the nature of the carbonyl compound from which the enamine was made. Even with this complication the availability of iminium salts is not impaired since the protonation reaction is usually carried out at higher temperatures than —70°. Structurally complicated enamines such as trichlorovinyl amine can be readily protonated (17,18). 

The initial investigation of the reaction of aldehydes and ketones with complex secondary amine salts was that of Lamchen et al. (11). A few salts had been observed before by Zincke and Wiirker (24), but the reaction was not examined in detail. Lamchen et al. prepared a number of compounds that were presumed to be iminium salts. The amine salts were halostannates, halobismuthates, haloantimonates, and hexahaloplatinates. Among the reported products were N-ethylidenepiperidinium (13) and N-cinnamili-denetetrahydroisoquinolinium (14) salts. 

A recent adaptation of the procedure employing perchlorate and fluoro-borate salts has been reported by Leonard and Paukstelis (J5). This report includes proof of structure by direct comparison to iminium salts prepared by protonation of enamines. The general reaction reported was that of a ketone or aldehyde with a secondary amine perchlorate to give iminium salts. A large structural variety of carbonyl compounds and several amine... 

In some cases Grignard reagents cause reduction of the iminium salt to the corresponding saturated amine (51a). 

It is not known whether the amine assists the elimination of the nitrogen, but that the iminium salt retains its stereochemistry has been demonstrated (709). When a mixture of 68 and 69of 1 5 ratio is treated with diazomethane, the ratio of 70 71 obtained in 75% yield and determined spectroscopically was still 1 5. The traw-N-isopropyl-N-methylisobutylidinium perchlorate (69) was prepared by alkylation of an aldimine salt with diazomethanc and... 

The reaction of a large number of other nucleophiles with iminium salts will at least be mentioned in this section. Among the nucleophiles which react with iminium salts are cyanide 48,115-119), mercaptide 48), alkoxide 48), amine 120), azide 44), phosphine 44), and phosphate ester 44). One can say with little reservation that almost all nucleophiles will react... 

The reaction of other nucleophiles such as amines 123,124), hydroxyl-amines, various carbanions, and hydroxide 120) have been tried but not examined in detail. Hydrolysis of iminium salts is covered elsewhere 123). 

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). 

The reactions with nucleophiles include a wide variety such as amines, sulfides (133,135), diazomethane (111), and others. Of particular interest were the reactions of such intermediate iminium salts with 2,3-dimethyl-butadiene to give cyclic products as shown in the reaction of N-bromo-methylpiperidine and N-bromo- and N-chloromethyldiethylamine (134). 

It has been shown (140) that enamines react as well, if not better, under the conditions of the Leuckart-Wallach reaction to give amines than do ketones in the presence of ammonia, primary amines, or secondary amines. This implies that in the Leuckart-Wallach reaction the pathway may be through the enamine and, of course, the iminium salt. The Leuckart-Wallach reaction has been reviewed (141). Examples of enamines reduced under the conditions of the Leuckart-Wallach reaction are listed in Table 12. 

The configuration of the amine was retained, except in the case of amino acid derivatives, which racemized at the stage of the pyridinium salt product. Control experiments showed that, while the starting amino acid was configurationally stable under the reaction conditions, the pyridinium salt readily underwent deuterium exchange at the rz-position in D2O. In another early example, optically active amino alcohol 73 and amino acetate 74 provided chiral 1,4-dihydronicotinamide precursors 75 and 76, respectively, upon reaction with Zincke salt 8 (Scheme 8.4.24). The 1,4-dihydro forms of 75 and 76 were used in studies on the asymmetric reduction of rz,>S-unsaturated iminium salts. 

Iminium ions bearing an electron-withdrawing group bonded to the sp carbon of the iminium function are very reactive dienophiles. Thus, iminium ions 26 generated from phenylglyoxal (Scheme 6.15, R = Ph) or pyruvic aldehyde (R = Me) with methylamine hydrochloride, react with cyclopenta-diene in water at room temperature with good diastereoselectivity [25] (Scheme 6.15). If glyoxylic acid is used, the formation of iminium salt requires the free amine rather than the amine hydrochloride. 

Similarly, the iminium salt 38 exposed to 5.0m LP-DE afforded only 13% of tricyclic amine 39, while heating 38 in water gave the Diels-Alder adduct 39 in high yield (Equation 6.2). 

This is the most common method for the preparation of enamines and usually takes place when an aldehyde or ketone containing an a hydrogen is treated with a secondary amine. The water is usually removed azeotropically or with a drying agent, but molecular sieves can also be used. Stable primary enamines have also been prepared.Enamino-ketones have been prepared from diketones and secondary amines using microwave irradiation on silica gel. ° Secondary amine perchlorates react with aldehydes and ketones to give iminium salts (2, p. 1178). Tertiary amines can only give salts (12). 

Iminium salts give tertiary amines directly, with just R adding ... 

Betalains consist of two groups of pigments of similar structure, the yellow compounds classed as betaxanthins and the purple as betacyanins [14]. Both groups contain a betalamic acid residue coupled to an amine or an amino acid to form an iminium salt. Whereas the amino components of the betaxanthins vary considerably. 

Addition of Vinyl and Aryl Groups. The reaction of aromatic radicals, generated by decomposition of diazonium salts, with iminium salts in the presence of TiCE in aqueous media produces secondary amines (Eq. 11.53).91 The iminium salts are formed in situ from aromatic amines and aldehydes. 

Petasis reported an efficient addition of vinyl boronic acid to iminium salts.92 While no reaction was observed when acetonitrile was used as solvent, the reaction went smoothly in water to give allyl amines (Eq. 11.54). The reaction of the boron reagent with iminium ions generated from glyoxylic acid and amines affords novel a-amino acids (Eq. 11.55). Carboalumination of alkynes in the presence of catalytic Cp2ZrCl2 and H2O affords vinylalane intermediates, which serve as nucleophiles in the subsequent addition to enantiomerically enriched... 

The excellent reducing properties of potassium tetracarbonylhydrido-ferrate have been used to good effect in providing an efficient general piperidine synthesis from alkyl and aryl amines and glutaraldehyde210 (Scheme 138). The reaction probably proceeds via reduction of intermediate Schiff bases and cyclization via the iminium salt. 

The TEAF system can be used to reduce ketones, certain alkenes and imines. With regard to the latter substrate, during our studies it was realized that 5 2 TEAF in some solvents was sufficiently acidic to protonate the imine (p K, ca. 6 in water). Iminium salts are much more reactive than imines due to inductive effects (cf. the Stacker reaction), and it was thus considered likely that an iminium salt was being reduced to an ammonium salt [54]. This explains why imines are not reduced in the IPA system which is neutral, and not acidic. When an iminium salt was pre-prepared by mixing equal amounts of an imine and acid, and used in the IPA system, the iminium was reduced, albeit with lower rate and moderate enantioselectivity. Quaternary iminium salts were also reduced to tertiary amines. Nevertheless, as other kinetic studies have indicated a pre-equilibrium with imine, it is possible that the proton formally sits on the catalyst and the iminium is formed during the catalytic cycle. It is, of course, possible that the mechanism of imine transfer hydrogenation is different to that of ketone reduction, and a metal-coordinated imine may be involved [55]. 

The reduction of imines and iminium salts present a particular difficulty in that those which are N-substituted can exist in different geometrical isomers that are reduced at different rates and with different selectivities. One way to overcome this problem is to use cyclic imines that can exist only as cis isomers. Although these are good substrates, this is not a general solution. The cyclic amines produced by transfer hydrogenation, together with best reported enantiomeric excesses, are listed in Table 35.6. Primary amines are difficult to pre-... 

Quaternary ammonium cyanoborohydrides have been used for the reduction of iminium salts [14] and in the reductive amination of aldehydes and ketones [15]. 

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