Carbonyl compounds ortho acid synthesis

In the Skraup and Doebner-Miller synthesis of quinoline, primary arylamines with an unsubstituted ortho position react with a,p-unsaturated carbonyl compounds in an acid medium in the presence of an oxidizing agent (nitroarene, AS2O5) ... 

Michael addition of metal enolates to a,/3-unsaturated carbonyls has been intensively studied in recent years and provides an established method in organic synthesis for the preparation of a wide range of 1,5-dicarbonyl compounds (128) under neutral and mild conditions . Metal enolates derived from ketones or esters typically act as Michael donors, and a,-unsaturated carbonyls including enoates, enones and unsaturated amides are used as Michael acceptors. However, reaction between a ketone enolate (125) and an a,/3-unsaturated ester (126) to form an ester enolate (127, equation 37) is not the thermodynamically preferred one, because ester enolates are generally more labile than ketone enolates. Thus, this transformation does not proceed well under thermal or catalytic conditions more than equimolar amounts of additives (mainly Lewis acids, such as TiCU) are generally required to enable satisfactory conversion, as shown in Table 8. Various groups have developed synthons as unsaturated ester equivalents (ortho esters , thioesters ) and /3-lithiated enamines as ketone enolate equivalents to afford a conjugate addition with acceptable yields. 

Deactivation of the amide carbonyl by N-lithiation directs the second lithiation to the ortho position to the amide group. The dilithio compound is stabilized by intramolecular chelation. Larcheveque and coworkers used a chiral amide that was obtained from the reaction between an optically active epihydrin and an anhydride for the asymmetric synthesis of ketones or of substituted acids (equation 13). 

Dreyer and Brenner 62) isolated two new quinazoline alkaloids from seed husks of Zanthoxylum arborescens. The major compound, C17H16N2O2 exhibits a blue fluorescence on TLC. In the H-nmr spectrum the downfield aromatic quartet at 8 8.12 (J = 7.1 Hz) and a one-proton triplet at 8 7.8 (J = 7 Hz), each further split (J = 1 Hz) suggest the presence of four adjacent aromatic protons on an ortho-substituted benzene ring. The aromatic quartet farthest downfield at 8 8.12 indicates the presence of a / r/-related carbonyl group. Two two-proton multiplets (8 2.93—4.40) are consistent with the presence of a 2-phenylethyl system. Other nmr data, in light of the mass spectrum, suggest the presence of an N-methylanthranilic acid system. These characteristics could be assembled in two different ways, leading to structures (7) (Chart 1) and (31). C-spectroscopy and synthesis from N-methylisatoic anhydride and 2-phenylethylamine finally allowed elucidation of the structure. The synthetic product, l-methyl-3-(2 -phenylethyl)-lH,3H-quinazolin-2,4-dione (7) was identical with the alkaloid. 

The reaction between amino group (-NH2) and a carbonyl group (C=0) elsewhere in the same molecule has been used in the synthesis of many heterocyclic compounds. For example as shown in Equation 9.53, substituted quinolines can be produced by acid-catalyzed cyclization of the appropriate aminoketones (formed during the Friedlander synthesis, in this instance between propanone and ortho-aminobenzaldehyde, in an aldol-type reaction with loss of water this chapter, vide infra), and even more than one reaction can be induced to occur. Thus, in Equation 9.54,1,2-benzenediamine (ort/io-aminoaniline) undergoes acid-catalyzed addition to 2,3-butane-dione to produce 2,3-dimethyl-13-benzopyrazine (23-dime thy Iquinoxaline). ... 

The preparation of functionalized aryl boronic reagents can be achieved by directed metallation followed by a transmetallation of aryllithiums with organoboron compounds. Thus, Caron and Hawkins have described a directed ortho-metalla-tion of aryl neopentyl esters such as 1 for the synthesis of substituted ortho-horo-nyl neopentyl benzoates using lithium diisopropylamide (LDA) as the base and B(OiPr)3 as an in situ trap [3]. The crude boronic acids obtained by acidic hydrolysis were subsequently treated with ethanolamine and converted to stable diethanolamine complexes such as 2. This methodology allows the preparation of a new class of boronic acids with ortho-carbonyl substituents and other functionalities... 

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