Schiff bases enolates from

The equilibrium in the case of Schiff bases prepared from salicylaldehyde and 2-amino-, 2,3-diamino-, 2,6-diamino- and 3-aminomethylpyridine was studied by means of NMR, UV and IR spectroscopy and X-ray crystallography It was shown that the enol-imines were the predominant form in non-polar solvents, whereas in polar solvents a rapid tautomeric interconversion between the enol-imines and the keto-enamines as well as a slow hydrolysis were observed. The tendency to tautomeric interconversion was significant for the 2-(3-pyridylmethyliminomethyl)phenol 45 while in the case of other Schiff bases it was very low. 

Reactions exhibiting diastereofacial selectivity, which occur when the imine or the enolate contains an endogenous stereocenter or a chiral auxiliary, have important applications for the synthesis of optically active 3-l ctams and 3-amino carboxylic acid derivatives. Early work by Furukawa et al. has demonstrated the viability of preparing optically active 3-amino acids from chiral imines. For example, the Schiff base derived from (5)-a-methylbenzylamine (110) reacts with Reformatsky reagent (111) to give, after hydrolysis and removal of the chiral auxiliary, 3-amino-2,2-dimethyl-3-phenylpropionic acid (112) in 33% ee (Scheme 21). Similar Reformatsky reactions have been performed using (-)-menthyl esters but the enantiomeric excess values are lower. ... 

NMR studies have been mainly applied to elucidating the structural features of Schiff bases in solution. These studies are mainly concerned with Schiff bases derived from benzaldehyde and its substituents, / -diketones, o-hydroxyacetophenones and o-hydroxyacetonaphthones. They were devoted to obtaining an insight into the keto-enol equilibrium (Scheme 1), syn and anti isomerism and steric distortions in different kinds of solvents. Relevant data and results are described in the following sections. 

Nuclear magnetic resonance studies were also made of Schiff bases obtained from amines and aliphatic /9-diketones. These compounds can exist in any of three tautomeric forms, the keto-imine (10), the keto-enamine (11) and the enol-imine (12) . It was found that in... 

When monomeric metaphosphate anion POf (102) is generated form the phos-phonate dianion 170 in the presence of the hindered base 2,2,6,6-tetramethylpiper-idine, it undergoes reaction with added carbonyl compounds147), Thus, it phosphoryl-ates acetophenone to yield the enol phosphate, whereas in the presence of acetophenone and aniline the Schiff base is formed from both compounds, probably by way of the intermediate C6H5—C(CH3) (OPO e) ( NH2C6HS). This reactivity pattern closely resembles that of monomeric methyl metaphosphate 151 (see Sect. 4.4.2). 

Potassium enolates derived from the chiral Schiff bases obtained by reaction of racemic a-amino esters with 2-hydroxypinan-3-one undergo diastereoselective protonation, as evidenced by release of optically active a-amino esters on subsequent cleavage of the imine (Scheme 5). ... 

There are several classes of alkaloids. Among these are purines such as xanthine and caffeine, ter-penes (Chapter 22), polyketides (Chapter 21), and alkaloids derived from amino acids. The basic amino acids ornithine, arginine, histidine, and lysine as well as the aromatic amino acids, anthranilate, and nicoti-nate are some of the starting materials.199 201 Robinson202 203 in 1917 recognized that many alkaloids are derived directly from aromatic amino acids. He proposed that alkaloids arise from Mannich reactions (Eq. 25-12) in which an amine and an aldehyde (probably through a Schiff base) react with a nucleophilic carbon such as that of an enolate anion. Many of the... 

In addition, chiral Schiff base catalysts, which were developed previously for the Strecker reaction, were also found to be suitable catalysts for the Mannich reaction starting from imines and enolates [36, 37]. Very recently, further efficient organocatalysts for the Mannich reaction, such as chiral pyrrolidinyltetrazole and chiral binaphthyl phosphoric acids, have been reported [38]. 

Hodge7 has advanced several possible routes for the conversion of the enol form of the 1-amino-l-deoxy-2-ketose into melanoidin, and the evidence to support these mechanisms is considerable. Thus, the enol may be converted into the Schiff base of a furaldehyde, or to a reductone by loss of water. It may also be broken down into smaller fragments (for example, hydroxy-2-propanone or pyruvaldehyde), which react further with amino compounds. The enol may also react with an a-amino acid and be converted to an aldehyde by a Strecker degradation. The compounds thus formed from... 

The enolate derived from the Schiff base 3 has been added to a,/ -unsaturated esters and ketones with a high level of enantioselectivity. For example, in the presence of 10 mol% lb, the enolate of the glycine derivative 3 was added to cyclohexenone with excellent diastereo-selectivity to give the ketoester 20 with >99% ee (Scheme 7) [15]. Promising results have also been obtained in the Michael additions of malonates to chalcone deriviatives [16], The novel cinchonidinium bromide lg was found to be the most effective catalyst for this transformation, yielding the Michael adduct 21 with 70% ee (Scheme 8). 

Pyrazines are formed from transamination reactions, in addition to carbon dioxide and formaldehyde. A requirement is that the carbonyl compound contains a dione and the amino group is alpha to the carboxyl group (16). If the hydrogen on the ct-carbon oI the amino acid is substituted, a ketone is produced. Newell (17) initially proposed a pyrazine formation mechanism between sugar and amino acid precursors. (See Figure 3). The Schiff base cation is formed by addition of the amino acid to the anomeric portion of the aldo-hexose, with subsequent losses of vater and a hydroxyl ion. Decarboxylation forms an imine which can hydrolyze to an aldehyde and a dienamine. Enolization yields a ketoamine, vhich dissociates to amino acetone and glyceraldehyde. 2,5-Dimethylpyrazine is formed by the condensation of the tvo molecules of amino acetone. 

Stabilization of enolate anions generated from abstraction of a proton a to a carboxylate Hydrolysis, phosphoryl group transfer via hydrolytic nucleophilic substitution Stabilization of diverse oxyanion intermediates via metal-assisted catalysis Schiff base dependent formation of an electron sink ... 

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