Diamines, from addition imines

The reductive couphng of imines can follow different pathways, depending on the nature of the one-electron reducing agent (cathode, metal, low-valent metal salt), the presence of a protic or electrophihc reagent, and the experimental conditions (Scheme 2). Starting from the imine 7, the one-electron reduction is facihtated by the preliminary formation of the iminiiim ion 8 by protonation or reaction with an electrophile, e.g., trimethylsilyl (TMS) chloride. Alternatively, the radical anion 9 is first formed by direct reduction of the imine 7, followed by protonation or reaction with the electrophile, so giving the same intermediate a-amino radical 10. The 1,2-diamine 11 can be formed from the radical 10 by dimerization (and subsequent removal of the electrophile) or addition to the iminium ion 8, followed by one-electron reduction of the so formed aminyl radical. In certain cases/conditions the radical 9 can be further reduced to the carbanion 12, which then attacks the... 

Synthesis of 1,6-diaminohexane from the corresponding diol and ammonia is complicated by cyclization either via the amino alcohol intermediate or by disproportionation of the diamine (Scheme 8) [24], The best selectivity was achieved with Raney Ni in dioxane - 67 % for the diamine and 33 % for hexamethylenei-mine at 58% conversion. The selectivity for 1,6-diaminohexane could be increased to nearly 100 % by partial recycling of the cyclic imine, i. e. no additional imine was formed in the equilibrium reaction. 

In addition to their antiknock properties, organic lead compounds possess bactericidal properties and motor fuels with lead are known to inhibit bacterial growth during storage in contact with water. With the disappearance of lead-based compounds, it is necessary to incorporate biocides from the cyclic imine family, (piperidine, pyrrolidine, hexamethyleneimine), alkylpropylene diamines or imidazolines (Figure 9.2). 

The kinetics of the hydrolysis of some imines derived from benzophenone anc primary amines revealed the normal dependence of mechanism on pH with ratedetermining nucleophilic attack at high pH and rate-determining decomposition of the tetrahedral intermediate at low pH. The simple primary amines show a linear correlation between the rate of nucleophilic addition and the basicity of the amine Several diamines which were included in the study, in particular A, B, and C, al showed a positive (more reactive) deviation from the correlation line for the simple amines. Why might these amines be more reactive than predicted on the basis of thei ... 

The condensation of nitro compounds and imines, the so-called aza-Henry or nitro-Mannich reaction, has recently emerged as a powerful tool for the enantioselective synthesis of 1,2-diamines through the intermediate /3-amino nitro compounds. The method is based on the addition of a nitronate ion (a-nitro carbanion), generated from nitroalkanes, to an imine. The addition of a nitronate ion to an imine is thermodynamically disfavored, so that the presence of a protic species or a Lewis acid is required, to activate the imine and/or to quench the adduct. The acidic medium is compatible with the existence of the nitronate anion, as acetic acid and nitromethane have comparable acidities. Moreover, the products are often unstable, either for the reversibility of the addition or for the possible /3-elimination of the nitro group, and the crude products are generally reduced, avoiding purification to give the desired 1,2-diamines. Hence, the nitronate ion is an equivalent of an a-amino carbanion. 

Double asymmetric induction operates when the azomethine compound is derived from a chiral a-amino aldehyde and a chiral amine, e.g., the sulfin-imine 144 [70]. In this case, the R configuration at the sulfur of the chiral auxihary, N-tert-butanesulfinamide, matched with the S configuration of the starting a-amino aldehyde, allowing complete stereocontrol to be achieved in the preparation of the diamine derivatives 145 by the addition of trifluo-romethyl anion, which was formed from trifluoromethyltrimethylsilane in the presence of tetramethylammonium fluoride (Scheme 23). The substituents at both nitrogen atoms were easily removed by routine procedures see, for example, the preparation of the free diamine 146. On the other hand, a lower diastereoselectivity (dr 80 20) was observed in one reaction carried out on the imine derived from (it)-aldehyde and (it)-sulfinamide. 

Cyclic imines 8 and 9 are intermediates or models of biologically active compounds and can be reduced with ee-values of 88 to 96% using Ti-ebthi, Ir-bcpm or Ir-binap in the presence of additives (entries 5.7, 5.9), as well as with the transfer hydrogenation catalyst Ru-dpenTs (entries 5.8, 5.10-5.12). As pointed out earlier, Ru-diphosphine-diamine complexes are also effective for imines, and the best results for 7 and 8a were 88% and 79% ee, respectively [36]. Azirines 10 are unusual substrates which could be transfer-hydrogenated with a catalyst prepared in situ from [RuCl2(p-cymene)]2 and amino alcohol L12, with ee-values of 44 to 78% and respectable TOFs of up to 3000 (entry 5.13). 

Diamine 8 is obtained from hydrogenation of amino imine 7 which can be formed by direct addition of primary amine to amino imine [1] or to l-aza-l-cycloheptene 3. 

A pseudo-C2-symmetric tertiary diamine derived from (1 S2S)-(+)-pseudoephedrinc (17, R1 = Me, R2 = Ph) has been prepared and tested in the enantioselective addition of methyllithium to aromatic imines.39 It shows comparable ee and better reactivity than a genuinely C2-symmetric relative [17, R1, R2 = -(CH2)4-]. 

Preparative Methods (i) preparation of racemic DPEN and its optical resolution Reaction of benzil and cyclohexanone in the presence of ammonium acetate and acetic acid at reflux temperature gives a cyclic bis-imine (1) (eq 1). Stereoselective reduction of the bis-imine with lithium in THF-liquid ammonia at —78 °C followed by addition of ethanol, then hydrolysis with hydrochloric acid and neutralization with sodium hydroxide produces the racemic diamine (2). Recrystallization of the l-tartaric acid salt from a 1 1 water-ethanol mixture followed by neutralization with sodium hydroxide, recrystallization from hexane results in (5,5)-DPEN (3) as colorless crystals. 

Muller and coworkers have recently developed a coupling-isomerization reaction, initially identified as a side reaction which occurred under standard Sonogashira conditions [79]. As demonstrated below, the coupling reaction is followed by a shuffling of oxidation states via an alkyne-allene isomerization [80]. The product, a,P-unsaturated ketone 146, is reminiscent of a product which would be obtained from a Heck reaction. The utility of this reaction was further demonstrated when diamine 147 was added to the reaction pot. Following a conjugate addition reaction and imine formation, compound 148 resulted from the three-component, one-pot reaction sequence enabled by the coupling-isomerization reaction. 

Masked forms of the monoimine from glyoxal have been extensively used as chiral precursors to a amino acids and a amino aldehydes (Figure 1.3) [33]. For example, glyoxal can be converted into aminal 6 in 90% yield upon treatment with diamine 5 (Scheme 1.9) [33b]. Imine formation, followed by Grignard addition, leads to amine 7 in 86% yield as a single diastereomer. Acid hydrolysis affords the a amino aldehyde 9 in good yields. 

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