1.2- Diamines ketones

Finally, in the last step, the chelating auxiliary had to be removed Ideally, one would like to convert 4.54 into ketone 4.55 via a retro Mannich reaction. Unfortunately, repeated attempts to accomplish this failed. These attempts included refluxing in aqueous ethanol under acidic and basic conditions and refluxing in a 1 1 acetone - water mixture in the presence of excess paraformaldehyde under acidic conditions, in order to trap any liberated diamine. Tliese procedures were repeated under neutral conditions in the presence of copper(II)nitrate, but without success. 

Synthesis and Properties. A number of monomers have been used to prepare PQs and PPQs, including aromatic bis((9-diamines) and tetramines, aromatic bis(a-dicarbonyl) monomers (bisglyoxals), bis(phenyl-a-diketones) and a-ketones, bis(phenyl-a-diketones) containing amide, imide, and ester groups between the a-diketones. Significant problems encountered are that the tetraamines are carcinogenic, difficult to purify, and have poor stabihty, and the bisglyoxals require an arduous synthesis. 

One-part urethane sealants (Table 3) are more compHcated to formulate on account of an undesirable side reaction between the prepolymer s isocyanate end and water vapor which generates carbon dioxide. If this occurs, the sealant may develop voids or bubbles. One way to avoid this reaction is to block the isocyanate end with phenol and use a diketamine to initiate cure. Once exposed to moisture, the diketamine forms a diamine and a ketone. The diamine reacts with the isocyanate end on the prepolymer, creating a cross-link (10). Other blocking agents, such as ethyl malonate, are also used (11). Catalysts commonly used in urethane formulations are tin carboxylates and bismuth salts. Mercury salt catalysts were popular in early formulations, but have been replaced by tin and bismuth compounds. 

The type of synthesis in which the two-atom fragment supplies C-5 + C-6 is uncommon but useful in preparing pyrimidine- and 5,6,7,8-tetrahydroquinazoline-2,4-diamines. Thus, dicyandiamide (S78) with benzyl methyl ketone (S77) yields 6-methyl-5-phenylpyrimidine-2,4-diamine (S79), or with acetophenone it yields 6-phenylpyrimidine-2,4-diamine (62JOC2708). Likewise, with cyclohexanone it yields the tetrahydroquinazolinediamine (SSO) and by using N- substituted dicyandiamides, 2- and/or 4-alkylamino groups may be introduced (65JOC1837). 

A considerable number of non-cross-linked aromatic and heterocyclic polymers has been produced. These include polyaromatic ketones, aromatic and heterocyclic polyanhydrides, polythiazoles, polypyrazoles, polytriazoles, poly-quinoxalines, polyketoquinolines, polybenzimidazoles, polyhydantoins, and polyimides. Of these the last two have achieved some technical significance, and have already been considered in Chapters 21 and 18 respectively. The most important polyimides are obtained by reacting pyromellitic dianhydride with an aromatic diamine to give a product of general structure (Figure 29.17). 

The ketimine is an acetone-blocked diamine. The synthesis and applications of ketimines will be discussed later. The curing concept for the adhesive is shown in Fig. 7. Phenol-blocked prepolymers would normally unblock at approximately 150°C. However, an aliphatic diamine, generated by the hydrolysis of the ketimine to an aliphatic diamine and ketone as a result of exposure to the moisture in the air, is sufficient to cure the windshield adhesive at room temperature. 

Several blocked diamines or amino-alcohols are commercially available. The aldimine is an aldehyde-blocked diamine. The ketimine is a ketone-blocked diamine. The oxazolidine is a five-membered ring containing oxygen and nitrogen. The oxazolidine ring shown below is an aldehyde-blocked amino alcohol. The basic synthetic concepts of an aldimine, a ketimine, and an oxazolidine are shown below ... 

Once the adhesive system is applied, water reacts preferentially with the more reactive ketimine, instead of with the slower reacting isocyanate. In the presence of water, the ketimine unblocks to reform the ketone and diamine. Once formed, the diamine will react quickly with the isocyanate to form a polyurea. 

Both von Hirsch 1U) and Weingarten and White 39) have reported the amination of aldehydes and ketones by tris(dimethylamino)arsine (142) to yield the corresponding gem diamine (143) or enamine (144). Von Hirsch s... 

A reagent more reactive than tris(dimethylamino)arsine employed by Weingarten and White 39) was tetrakis(dimethylamino)titanium (145). With this compound it was possible to prepare N,N-dimethyl(l-isopropyl-2-methylpropcnyl)amine (147) from diisopropyl ketone. Weingarten and White 39) have suggested a possible mechanism for this reaction (see p. 88). If benzaldehyde 39,111), formaldehyde 111), or acetaldehyde 39) is used, the corresponding gem diamine or aminal (143) is formed. 

The reaction seems to involve double addition of ammonia to the ketone 102 (at the methoxyethenyl group and the triple bond) to form the diamine 104 which further undergoes cyclization to aminopyridine 103 by elimination of water and methanol. 

A variation on this theme consists in first displacement of the chlorine in 73 with ethylaminoethanol. Reductive amination of the ketone by means of ammonia in the presence of hydrogen gives the hydroxylated diamine (77). Use of this intermediate to effect displacement of the halogen at the 4 position of 70 affords hydroxychloroquine (78). ... 

Step 1 of Figure 29.14 Transimination The first step in transamination is trans-imination—the reaction of the PLP—enzyme imine with an a-amino acid to give a PLP—amino acid imine plus expelled enzyme as the leaving group. The reaction occurs by nucleophilic addition of the amino acid -NH2 group to the C=N bond of the PLP imine, much as an amine adds to the C=0 bond of a ketone or aldehyde in a nucleophilic addition reaction (Section 19.8). The pro-tonated diamine intermediate undergoes a proton transfer and expels the lysine amino group in the enzyme to complete the step. 

Best results are obtained when the reaction is carried out under acidic conditions. The products are isolated in the form of their stable salts 3 with hydrochloric, perchloric or sulfuric acid.256-257 a-Hydroxymethylene ketones do not condense with benzene-1,2-diamine to give benzodiazepines if the carbonyl group is adjacent to an aromatic ring.258... 

Both anodic and general inhibitors are nonpassivating and are suitable for use with hydrochloric acid-based cleaners. Other inhibitor groups include filming amines such as polymethylimine and diamines, the rosin-amine ketones, and also some of the imidazoline surfactants. The imidazolines provide increased protection at levels up to their critical miscelle concentration (CMC), above which there is a leveling off as a thick, adherent diffusion barrier is formed. 

Cyclic 1,2-diamines are cleaved to diketones with dimethyl dioxirane. a-Diketones and a-hydroxy ketones are also cleaved by alkaline H202. HIO4 has... 

On the other hand, the enantioselective 1,4-addition of carbanions such as enolates to linear enones is an interesting challenge, since relatively few efficient methods exist for these transformations. The Michael reaction of p-dicarbonyl compounds with a,p-unsaturated ketones can be catalysed by a number of transition-metal compounds. The asymmetric version of this reaction has been performed using chiral diol, diamine, and diphosphine ligands. In the past few years, bidentate and polydentate thioethers have begun to be considered as chiral ligands for this reaction. As an example, Christoffers et al. have developed the synthesis of several S/O-bidentate and S/O/S-tridentate thioether... 

It was independently found by two groups that the exo-diol derived from bis(camphorsulfonyl)-substituted tra .s-cyclohexane-1,2-diamine ligand (HOCSAC) was an excellent promoter for the enantioselective addition of dialkyIzinc reagents to any type of ketones, even dialkyl ketones, in the presence of Ti(Oi-Pr)4. As shown in Scheme 4.11, excellent enantioselectivities of up to 99% ee were obtained in these conditions in combination with high yields and with a low catalyst loading of 2-10 mol%. 

Scheme 9.18 Ru-catalysed reductions of ketones with (r 6-arene)-Af-perfluorosulfonyl-1,2-diamine and Af-(Af,Af-dialkylamino)sulfamoyl-l,2-diamine ligands.

Manufacture of ruthenium precatalysts for asymmetric hydrogenation. The technology in-licensed from the JST for the asymmetric reduction of ketones originally employed BINAP as the diphosphine and an expensive diamine, DAIPEN." Owing to the presence of several patents surrounding ruthenium complexes of BINAP and Xylyl-BINAP, [HexaPHEMP-RuCl2-diamine] and [PhanePHOS-RuCl2-diamine] were introduced as alternative catalyst systems in which a cheaper diamine is used. Compared to the BINAP-based systems both of these can offer superior performance in terms of activity and selectivity and have been used in commercial manufacture of chiral alcohols on multi-100 Kg scales. 

The reductive alkylation of a primary amine with ketone leads to the formation of a stable imine. In the presence of hydrogen and a hydrogenation catalyst, the imine is reduced to a secondary amine. Similarly, a diamine reacts stepwise to form dialkylated secondary amines. However, several side reactions are possible for these reactions as outlined by Greenfield (12). The general scheme depicting the reaction between primary amine or diamine to yield secondary amine through a Schiff base is shown in Figure 17.1. 

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