Carboxylic acid derivatives acidity/basicity

In base the tetrahedral intermediate is formed m a manner analogous to that pro posed for ester saponification Steps 1 and 2 m Figure 20 8 show the formation of the tetrahedral intermediate m the basic hydrolysis of amides In step 3 the basic ammo group of the tetrahedral intermediate abstracts a proton from water and m step 4 the derived ammonium ion dissociates Conversion of the carboxylic acid to its corresponding carboxylate anion m step 5 completes the process and renders the overall reaction irreversible... 

These derivatives are prepared to protect a-hydroxy carboxylic acids they are cleaved by acidic hydrolysis of the acetal structure (HCl, DMF, 50°, 7 h, 71% yield), or basic hydrolysis of the lactone. ... 

Acidic and basic hydrolysis of ethyl 4-oxo-4//-pyrido[l, 2-u]pyrimidin-3-carboxylates gave 3-carboxylic acid derivatives (OlMIPl). Stirring rerr-butyl ( )-3-(2-hydroxy-8-[2-(4-isopropyl-l, 3-thiazol-2-yl)-l-ethenyl]-4-oxo-4//-pyrido[l,2-u]pyrimidin-3-yl)-2-propenoate in CF3CO2H at room temperature yielded ( )-3-substituted 2-propenoic acid. 

Subsequently it was found140 that ethyl 2-alkyl-1//-azepine-1-carboxylates can be isolated from a mixture of isomeric 1//-azepines by stirring the mixture with potassium hydroxide in ethanol at room temperature. Apparently, this method, which is limited to 2-alkylated azepines, depends on the slower rate of hydrolysis (and subsequent decomposition of the resulting 1H-azepine-l-carboxylic acid) of the sterically hindered 1-(ethoxycarbonyl) group. Although the yields of l//-azepines are poor (4-7%, vide supra), the method provides access to otherwise difficult to obtain, isomerically pure 2-alkyl-1//-azepines. Under the basic hydrolysis conditions aryl 2-alkyl-l//-azepine-1-carboxylates undergo transesterification to the l-(ethoxycarbonyl) derivatives. 

The condensation reactions described above are unique in yet another sense. The conversion of an amine, a basic residue, to a neutral imide occurs with the simultaneous creation of a carboxylic acid nearby. In one synthetic event, an amine acts as the template and is converted into a structure that is the complement of an amine in size, shape and functionality. In this manner the triacid 15 shows high selectivity toward the parent triamine in binding experiments. Complementarity in binding is self-evident. Cyclodextrins for example, provide a hydrophobic inner surface complementary to structures such as benzenes, adamantanes and ferrocenes having appropriate shapes and sizes 12) (cf. 1). Complementary functionality has been harder to arrange in macrocycles the lone pairs of the oxygens of crown ethers and the 7t-surfaces of the cyclo-phanes are relatively inert13). Catalytically useful functionality such as carboxylic acids and their derivatives are available for the first time within these new molecular clefts. 

This affinity for metals results not only from the structural organization of the new diacids but from stereoelectronic effects at carboxyl oxygen as well. The in-plane lone pairs of a carboxylate 18 differ in basicity by several orders of magnitude 16). Conventional chelating agents17> derived from carboxylic acids such as EDTA, 19a are constrained by their shape to involve the less basic anti lone pairs [Eq. (4)]. The new diacids are permitted the use of the more basic syn lone pairs in contact with the metal 19b. These systems represent a new type of chelate for highly selective recognition of divalent ions. 

Reactions of 2,3-dioxo-l,2,3,5,6,7-hexahydropyrido[l,2,3-carboxylic acids and the homologous acetic and propionic acids, prepared by basic hydrolysis of the corresponding ester, with amines, 28% NH4OH, and hydroxylamine derivatives in the presence of l-ethyl-3-[3-(dimethylamino)propyl]carbodiimide and hydroxybenztria-zole <1995BML1527>, 1995BML1533>, and in the presence of NEt3 and A, A -bis(2-oxo-3-oxazolidinyl)phosphinic... 

In the context of preparing benzothienyloxy phenylpropanamines as inhibitors of serotonin and norepinephrine uptake, a group from Eli Lilly and Company has developed a two-step synthesis of benzo[fo]thiophenes (Scheme 6.193) [354]. Thus, a 2-mercapto-3-phenylpropenoic acid derivative was cyclized with iodine in 1,2-dimethoxyethane at 120 °C to give 5-fluoro-4-methoxybenzothiophene-2-carboxylic acid in 67% yield. Decarboxylation under strongly basic conditions involving 1,8-di-azabicyclo[5.4.0]undec-7-ene (DBU) as base in N,N-dimethylacetamide (DMA) as... 

Although there is versatility in the synthetic methodologies of each individual quinolone antibacterial, two different methods are utilized to synthesize the basic skeleton of l,4-dihydro-4-oxoquinoline-3-carboxylic acid. The first method is based on the Gould-Jacobs reaction [9] using appropriately substituted aniline derivatives and diethyl ethoxymalonate, which results in the formation of the intermediate anilinomethylenemalonate. Further thermal cyclization of this intermediate followed by hydrolysis gives rise to the targeted l,4-dihydro-4-oxoquinoline-3-carboxylic acid, according to Scheme 1. 

E. Jacobson in 1882 fused phthalic anhydride with quinoline bases obtained from coal tar, which also contained quinaldine (136). He thus received quinophthalone (137). Quinophthalone derivatives bearing sulfonic or carboxylic acid functions represent suitable anionic dyes. Derivatives carrying basic side chains containing quarternary nitrogen, on the other hand, provide cationic dyes. The compounds are used especially as disperse dyes [1]. 

The reaction of 2- and 4-hydroxyadamantane-l-carboxylic esters with dibromo-carbene produces the corresponding 2- and 4-bromo derivatives (10-20%). Slow hydrolysis of the ester groups may also occur under the basic conditions. l-Acetyl-4-hydroxyadamantane yields 4-bromoadamantane-l -carboxylic acid (37%), as a result of a concomitant reaction with dibromocarbene and a haloform-type reaction [8]. 

In HO -catalyzed hydrolysis (specific base catalyzed hydrolysis), the tetrahedral intermediate is formed by the addition of a nucleophilic HO ion (Fig. 3.1, Pathway b). This reaction is irreversible for both esters and amides, since the carboxylate ion formed is deprotonated in basic solution and, hence, is not receptive to attack by the nucleophilic alcohol, phenol, or amine. The reactivity of the carboxylic acid derivative toward a particular nucleophile depends on a) the relative electron-donating or -withdrawing power of the substituents on the carbonyl group, and b) the relative ability of the -OR or -NR R" moiety to act as a leaving group. Thus, electronegative substituents accelerate hydrolysis, and esters are more readily hydrolyzed than amides. 

It is particularly interesting, that some titanium and tantalum carbene complexes olefinate derivatives of carboxylic acids. These reagents are, moreover, much less basic than phosphorus ylides, and thus enable the olefination of strongly C-H acidic carbonyl compounds. 

A number of 7V-carboxyalkyl and A-phosphonoalkyl substituted substrate analogue inhibitors have been examined [161,204-208]. These derivatives contain both the acidic carboxylate (or phosphonate) and basic amine functionalities in the vicinity of the scissile bond. Thus, they are capable both of electrostatic interaction with the active site Zn(II) and hydrogen bonding interactions with other active site residues. They are, however, only moderately potent collagenase inhibitors Table 8.18). The stereochemistry at the carbon atom to which the carboxylate moiety is bonded markedly influences the inhibitory potency of these derivatives ((197) vs. (198)). The phosphonate analogues of this class of derivatives have also been evaluated Table 8.18), but are not substantially better inhibitors than the carboxyl-ates. 

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