Carboxylate anion synthesis

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... 

The actual process of solid phase peptide synthesis outlined m Figure 27 15 begins with the attachment of the C terminal ammo acid to the chloromethylated polymer m step 1 Nucleophilic substitution by the carboxylate anion of an N Boc protected C terminal... 

Xanthine anions structure, 5, 509 Xanthine-8-carboxylic acid synthesis, 3, 308, 322 Xanthine oxidase... 

The anodic oxidation of the carboxylate anion 1 of a carboxylate salt to yield an alkane 3 is known as the Kolbe electrolytic synthesis By decarboxylation alkyl radicals 2 are formed, which subsequently can dimerize to an alkane. The initial step is the transfer of an electron from the carboxylate anion 1 to the anode. The carboxyl radical species 4 thus formed decomposes by loss of carbon dioxide. The resulting alkyl radical 2 dimerizes to give the alkane 3 " ... 

Step 2 of Figure 29.11 Decarboxylation The TPP addition product, which contains an iminium ion j8 to a carboxylate anion, undergoes decarboxylation in much the same way that a jB-keto acid decarboxylates in the acetoacetic ester synthesis (Section 22.7). The C=N+ bond of the pyruvate addition product acts... 

The oxygen nucleophiles that are of primary interest in synthesis are the hydroxide ion (or water), alkoxide ions, and carboxylate anions, which lead, respectively, to alcohols, ethers, and esters. Since each of these nucleophiles can also act as a base, reaction conditions are selected to favor substitution over elimination. Usually, a given alcohol is more easily obtained than the corresponding halide so the halide-to-alcohol transformation is not used extensively for synthesis. The hydrolysis of benzyl halides to the corresponding alcohols proceeds in good yield. This can be a useful synthetic transformation because benzyl halides are available either by side chain halogenation or by the chloromethylation reaction (Section 11.1.3). 

Radicals, (34), that subsequently dimerise, are also obtained through the anodic oxidation of carboxylate anions, RCO20, in the Kolbe electrolytic synthesis of hydrocarbons ... 

It is for long known that all aforementioned acids form stable complex (chelate) compounds with numerous, especially transition metal cations (see, e.g., Refs. [21, 22]). This fact is pointed out in practically all papers on the subject. However, the composition of complex compounds, their stability, the type of bonding between metal cations and carboxylic anions on various stages of the synthesis, and possible role of steric factors in these phenomena are discussed in a very small number of publications. 

The oxygen nucleophiles that are of primary interest in synthesis are the hydroxide ion (or water), alkoxide ions, and carboxylate anions, which lead, respectively, to alcohols, ethers, and esters. Because each of these nucleophiles can also act as a base, reaction conditions must be selected to favor substitution over elimination. 

Although organomagnesium compounds are not sufficiently reactive to add to carboxylate anions, alkyllithium compounds add quite well. A useful synthesis of methyl ketones involves the addition of methyllithium to the lithium salt of a carboxylic acid ... 

H,6H-Purine, l,7-dimethyl-6-oxo-UV spectra, 5, 517 7H,8H-Purine, 8-oxo-UV spectra, 5, 517 Purinecarboxamides reactions, 5, 550, 551 Purinecarboxylic adds reactions, 5, 550 Purine-6-carboxylic acids synthesis, 5, 593 Purine-8-carboxylic acids synthesis, 5, 593 Purine nucleotides biosynthesis, 1, 87-88 Purine[9,8-a]quinolines, 5, 566 Purines, 5, 499-605 aldehydes reactions, 5, 549 synthesis, 5, 593 alkylation, 5, 505, 528-538 amination, 5, 541-542 anions... 

Following the study of the simple coupling of radicals derived from the salt of a single carboxylic acid, it was found that the electrolysis of a mixture of carboxylate anions or of the salts of half esters of dicarboxylic acids increased the synthetic value of the method. This arises from the possibility of the formation of symmetrical and unsymmetrical coupled products of the derived radicals. These anodic syntheses are illustrated in the synthesis of hexacosane (Expt 5.11), sebacic acid (decanedioic acid), octadecanedioic acid and myristic acid (tetra-decanoic acid), in Expt 5.131. 

The stereoselective synthesis of 1,4-disubstituted-l,3-dienes proceeds by head-to-head oxidative coupling of two alkynes with formation of an isolable metallacyclic biscarbene ruthenium complex [23], as shown in Scheme 6. Several key experiments involving labeled reagents and stoichiometric reactions and theoretical studies support the formation of a mixed Fischer-Schrock-type biscarbene complex which undergoes protonation at one carbene carbon atom whereas the other becomes accessible to nucleophilic addition of the carboxylate anion (Scheme 6) [23]. 

Most commonly, the carboxylate anion is treated directly with an alkyl halide to give the corresponding ester212,371-373. A variety of metal counterions have been used to influence the yield, depending upon the substrates being used. Silver oxide has been used to assist this process in the synthesis of depsipeptide analogues from 2-bromocarboxamides and N-protected amino acids (equation 46)374. 

Under acidic conditions the equilibrium for the hydrolysis of an amide is driven toward the products by the protonation of the ammonia or amine that is formed. Under basic conditions the equilibrium is driven toward the products by the formation of the carboxylate anion, which is at the bottom of the reactivity scale. The pH of the final solution may need to be adjusted, depending on which product is to be isolated. If the carboxylic acid is desired, the final solution must be acidic, whereas isolation of the amine requires that the solution be basic. Several examples are shown in the following equations. Also, note that the last step of the Gabriel amine synthesis, the hydrolysis of the phthalimide (see Section 10.6 and Figure 10.5 on page 365), is an amide... 

Section I)13. In the case of the carboxylic anion, the lithiation of acyclic and cyclic orthoth-ioesters allows the preparation of intermediates XII12. All these stabilized organolithium reagents have been widely used in organic synthesis and in this section their application as acylating agents by this defensive strategy will be mainly considered. 

Scheme 20.2 Synthesis of zwitterions having carboxylate anion.

An alternative ester synthesis, the reaction of a carboxylate anion with an alkyl halide, was used by Madejewski [62] for the preparation of ( , )-l,9-dioxacy-clohexadeca-3,1 l-dien-2,10-dione (76) under dilution conditions. This 16-membe-red dilactone represents a precursor for the synthetic norpyrenophorin 77 a, the physiological activity of which corresponds to the one of the natural products pyrenophorin 77b and vermiculin 77c. The lactone 76 can be obtained in 77% yield by dimerization of ( )-7-bromo-2-heptenic acid (75) in DMF in the presence of potassium carbonate. 

An acid—base reaction forms a nucleophilic anion that can react with an unhindered alkyl halide— that is, CH3X or RCH2X—in an 5 2 reaction to form a substitution product. This alkylated imide is then hydrolyzed with aqueous base to give a 1° amine and a dicarboxylate. This reaction is similar to the hydrolysis of amides to afford carboxylate anions and amines, as discussed in Section 22.13. The overall result of this two-step sequence is nucleophilic substitution of X by NH2, so the Gabriel synthesis can be used to prepare 1° amines only. 

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