1 Carbon dioxide carboxylic acid ester

The reactions of Grignard reagents with different types of carbonyl groups yield a number of important functional groups. For example, reaction with formaldehyde yields 1° alcohols with higher aldehydes, 2° alcohols with ketones, 3° alcohols with esters, 3° alcohols with acyl halides, ketones with N,N-dialkylformamides, aldehydes and with carbon dioxide, carboxylic acids. 

Condensation of the 5-methyl group in (80) (R = Me, Et, Ph, SMe) with aromatic aldehydes leads to 5-styrylthiadiazoles (79). The action of carboxylic acid esters gives ethoxalyl derivatives (81) and that of isoamyl nitrite produces the oxime (82) (Scheme 20) <82AHC(32)285>. These reactions are restricted exclusively to the 5-methyl group in (80) (R = Me), reflecting the greater reactivity of substituents in the 5-position compared to the 3-position in 1,2,4-thiadiazoles. This point is further illustrated when (80) (R = Me) is selectively converted into the carboxylic acid (83) on treatment with n-butyllithium and carbon dioxide (Scheme 20) <84CHEC-I(6)463). 

Dioxathiolan-4-one 2-oxides (50) decompose rapidly in the presence of water and mineral acids to form a-hydroxy carboxylic acids, the detailed mechanism of hydrolysis being unknown. Nucleophilic attack on (50) by alcohols occurs at the acyl carbon atom and, with elimination of sulfur dioxide, gives a-hydroxy carboxylic acid esters (76CRV747). In a similar fashion to (50), l,2,3-oxadithiolan-5-one 2-oxides react rapidly with water to yield the parent a-mercaptocarboxylic acids (77MI43301). 

Formation of oxidation products such as carboxylic acids, esters, oxygenated aromatics, carbonyl compounds and carbon dioxide. 

In the case of the carbonyl compounds, the reactive center of the radiolytic reactions is the carbonyl group. The radiolytic reactions in carbonyls include formation in ketones of carbon monoxide and breakage of the C-H bond adjacent to the carbonyl, in carboxylic acids of carbon dioxide, and in esters of carbon monoxide and carbon dioxide. The products formed during radiolysis of acetone and methyl acetate are listed in Table 11.7. 

Two series of new polyphosphazenes were prepared by derivatization of preformed poly(methylphenylphosphazene), [Me(Ph)PN]p. This Involved Initial deprotonatlon of part of the methyl substituents with n-BuLi followed by treatment of the intermediate anion with carbon dioxide or with fluorinated aldehydes or ketones. With appropriate workup procedures, either carboxylic acid, ester, carboxylate salt, or fluorinated alcohol derivatives were obtained. These reactions and the characterization of the products are discussed In this paper. Related derivatization reactions are also discussed. 

We begin with reactions of polar organometallics with aldehydes, ketones, and v/c-dicarbonyl compounds (a-oxoaldehydes, 1,2-diketones, a-oxocarboxamides, and a-oxocarboxylic acids). Next we focus on carboxamides, lithium carboxylates, carboxylic acid esters, and acyl chlorides. Finally we turn to ketenes, (thio)isocyanates, and carbon dioxide, all featuring cumulated double bonds, and last but not least to carbon monoxide. 

Since the meso-ionic reactants (1) are readily accessible from (6) (and ultimately from mercaptoarylacetic acids), their conversion into isothiazoles (8) has been successfully developed as a synthetic route. They are treated with acetylene-mono- or -di-carboxylic acid esters in toluene at 60—100 °C, and afford, with loss of carbon dioxide, good yields of isothiazoles (8), probably by way of labile intermediates of type (7). 

We ve seen how Grignard reagents add to the carbonyl group of aldehydes ketones and esters Grignard reagents react m much the same way with carbon dioxide to yield mag nesium salts of carboxylic acids Acidification converts these magnesium salts to the desired carboxylic acids... 

The carbon-carbon bond forming potential inherent m the Claisen and Dieckmann reac tions has been extensively exploited m organic synthesis Subsequent transformations of the p keto ester products permit the synthesis of other functional groups One of these transformations converts p keto esters to ketones it is based on the fact that p keto acids (not esters ) undergo decarboxylation readily (Section 19 17) Indeed p keto acids and their corresponding carboxylate anions as well lose carbon dioxide so easily that they tend to decarboxylate under the conditions of their formation... 

In 1897, Reissert reported the synthesis of a variety of substituted indoles from o-nitrotoluene derivatives. Condensation of o-nitrotoluene (5) with diethyl oxalate (2) in the presense of sodium ethoxide afforded ethyl o-nitrophenylpyruvate (6). After hydrolysis of the ester, the free acid, o-nitrophenylpyruvic acid (7), was reduced with zinc in acetic acid to the intermediate, o-aminophenylpyruvic acid (8), which underwent cyclization with loss of water under the conditions of reduction to furnish the indole-2-carboxylic acid (9). When the indole-2-carboxylic acid (9) was heated above its melting point, carbon dioxide was evolved with concomitant formation of the indole (10). 

When a carbonyl group is bonded to a substituent group that can potentially depart as a Lewis base, addition of a nucleophile to the carbonyl carbon leads to elimination and the regeneration of a carbon-oxygen double bond. Esters undergo hydrolysis with alkali hydroxides to form alkali metal salts of carboxylic acids and alcohols. Amides undergo hydrolysis with mineral acids to form carboxylic acids and amine salts. Carbamates undergo alkaline hydrolysis to form amines, carbon dioxide, and alcohols. 

A V -Carbonyldiimidazole (CDI) is prepared in a convenient and safe procedure from phosgene and imidazole as a non-toxic crystalline compound (m.p. 116-118 °C).[5],[6] It reacts almost quantitatively at room temperature or by short and moderate heating with an equimolar quantity of a carboxylic acid in tetrahydrofuran, chloroform, or similar inert solvents within a few minutes to give the corresponding carboxylic acid imidazolide, which is formed under release of carbon dioxide, together with one equivalent of readily separable and recyclable imidazole.Thus, this reaction leads under very mild conditions to the activation of a carboxylic acid appropriate for transacylation onto a nucleophile with an alcohol to an ester, with an amino compound to an amide or peptide, etc. 

The reaction of a carboxylic acid with N,Af -carbonyldiimidazolellH33 (abbreviated as CDI), forming an imidazolide as the first step followed by alcoholysis or phenolysis of the imidazolide (second step), constitutes a synthesis of esters that differs from most other methods by virtue of its particularly mild reaction conditions.t41,[5] It may be conducted in two separate steps with isolation of the carboxylic acid imidazolide, but more frequently the synthesis is carried out as a one-pot reaction without isolation of the intermediate. Equimolar amounts of carboxylic acid, alcohol, and CDI are allowed to react in anhydrous tetrahydrofuran, benzene, trichloromethane, dichloromethane, dimethylformamide, or nitromethane to give the ester in high yield. The solvents should be anhydrous because of the moisture sensitivity of CDI (see Chapter 2). Even such unusual solvent as supercritical carbon dioxide at a pressure of 3000 psi and a temperature of 36-68 °C has been used for esterification with azolides.[6]... 

From the fact that malonic acid loses carbon dioxide on fusion and is converted into acetic acid, we conclude that a carbon atom has not the power of holding two carboxyl groups firmly. Now this also applies to all substituted malonic acids which can he readily obtained by hydrolysis from the esters. This constitutes a desirable simplification of the final product. 

Miscellaneous Reactions.—A full report has appeared of the reactions of carbon dioxide and carbon disulphide with tervalent phosphorus aryl esters and amines the products are ureas and thioureas, respectively.74 The suggested mechanism, previously invoked for similar reactions of carboxylic acids, involves the N-phosphonium salt (97). 

Plant. In plants, mevinphos is hydrolyzed to phosphoric acid dimethyl ester, phosphoric acid, and other less toxic compounds (Hartley and Kidd, 1987). In one day, the compound is almost completely degraded in plants (Cremlyn, 1991). Casida et al. (1956) proposed two degradative pathways of mevinphos in bean plants and cabbage. In the first degradative pathway, cleavage of the vinyl phosphate bond affords methylacetoacetate and acetoacetic acid, which may be precursors to the formation of the end products dimethyl phosphoric acid, methanol, acetone, and carbon dioxide. In the other degradative pathway, direct hydrolysis of the carboxylic ester would yield vinyl phosphates as intermediates. The half-life of mevinphos in bean plants was 0.5 d (Casida et ah, 1956). In alfalfa, the half-life was 17 h (Huddelston and Gyrisco, 1961). 

The nucleophile in biological Claisen reactions that effectively adds on acetyl-CoA is almost always malonyl-CoA. This is synthesized from acetyl-CoA by a reaction that utilizes a biotin-enzyme complex to incorporate carbon dioxide into the molecule (see Section 15.9). This has now flanked the a-protons with two carbonyl groups, and increases their acidity. The enzymic Claisen reaction now proceeds, but, during the reaction, the added carboxyl is lost as carbon dioxide. Having done its job, it is immediately removed. In contrast to the chemical analogy, a carboxylated intermediate is not formed. Mechanistically, one could perhaps write a concerted decarboxylation-nucleophilic attack, as shown. An alternative rationalization is that decarboxylation of the malonyl ester is used by the enzyme to effectively generate the acetyl enolate anion without the requirement for a strong base. 

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