Carboxylic amide derivative

Base-induced cleavage of non-enolizable ketones leading to carboxylic amide derivative and a neutral fragment in which the carbonyl group is replaced by a hydrogen. 

Trifluorobenzothiazol-2-yl-indolealkanoic acids, (V), and thieno[3.2-b]pyridine-2-carboxylic amide derivatives, (VI), prepared by Sredy (5) and Luzzio (6), respectively, were effective as antiangiogenic agents and used in treating hyperproliferative disorders such as cancer. 

Mukaiyama T, Iwasawa N. A facile asymmetric synthesis of P-substituted alkanoic acid the highly stereoselective Michael addition of Grignard reagents to a,p-unsaturated carboxylic amides derived from L-ephedrine. Chem. Lett. 1981 10 913-916. 

Activated Adds Chern. Soc. Rev. 1983, 12, 129 Angew. Chern. fnt. Ed. Engl. 1978, 17, 569. RC02F4 "activated acid" carboxylic acid derivative (ester, amide, etc.)... 

The conversion of carboxylic acid derivatives (halides, esters and lactones, tertiary amides and lactams, nitriles) into aldehydes can be achieved with bulky aluminum hydrides (e.g. DIBAL = diisobutylaluminum hydride, lithium trialkoxyalanates). Simple addition of three equivalents of an alcohol to LiAlH, in THF solution produces those deactivated and selective reagents, e.g. lithium triisopropoxyalanate, LiAlH(OPr )j (J. Malek, 1972). 

In synthetic target molecules esters, lactones, amides, and lactams are the most common carboxylic acid derivatives. In order to synthesize them from carboxylic acids one has generally to produce an activated acid derivative, and an enormous variety of activating reagents is known, mostly developed for peptide syntheses (M. Bodanszky, 1976). In actual syntheses of complex esters and amides, however, only a small selection of these remedies is used, and we shall mention only generally applicable methods. The classic means of activating carboxyl groups arc the acyl azide method of Curtius and the acyl chloride method of Emil Fischer. 

Conversions of acid anhydrides to other carboxylic acid derivatives are illustrated m Table 20 2 Because a more highly stabilized carbonyl group must result m order for nucleophilic acyl substitution to be effective acid anhydrides are readily converted to carboxylic acids esters and amides but not to acyl chlorides... 

The carbonyl group of an amide is stabilized to a greater extent than that of an acyl chlo ride acid anhydride or ester amides are formed rapidly and m high yield from each of these carboxylic acid derivatives... 

Mechanistically amide hydrolysis is similar to the hydrolysis of other carboxylic acid derivatives The mechanism of the hydrolysis m acid is presented m Figure 20 7 It proceeds m two stages a tetrahedral intermediate is formed m the first stage and disso ciates m the second... 

This chapter concerns the preparation and reactions of acyl chlorides acid anhydrides thioesters esters amides and nitriles These com pounds are generally classified as carboxylic acid derivatives and their nomenclature is based on that of carboxylic acids... 

Carboxylic acid derivative (Section 20 1) Compound that yields a carboxylic acid on hydrolysis Carboxylic acid de nvatives include acyl chlondes acid anhydndes esters and amides... 

Carboxylic acid derivatives on pyridopyrimidine rings appear to undergo normal reactions with electrophilic reagents, e.g. the 6-amide (70) is dehydrated to the 6-nitrile with phosphorus oxychloride. 

In most other reactions the azolecarboxylic acids and their derivatives behave as expected (cf. Scheme 52) (37CB2309), although some acid chlorides can be obtained only as hydrochlorides. Thus imidazolecarboxylic acids show the normal reactions they can be converted into hydrazides, acid halides, amides and esters, and reduced by lithium aluminum hydride to alcohols (70AHC(12)103). Again, thiazole- and isothiazole-carboxylic acid derivatives show the normal range of reactions. 

There are large differences in reactivity among the various carboxylic acid derivatives, such as amides, esters, and acyl chlorides. One important factor is the resonance stabilization provided by the heteroatom. This decreases in the order N > O > Cl. Electron donation reduces the electrophilicity of the carbonyl group, and the corresponding stabilization is lost in the tetrahedral intermediate. 

FIGURE 20.1 Structure, reactivity, and carbonyl-group stabilization in carboxylic acid derivatives. Acyl chlorides are the most reactive, amides the least reactive. Acyl chlorides have the least stabilized carbonyl group, amides the most. Conversion of one class of compounds to another is feasible only in the direction that leads to a more stabilized carbonyl group that is, from more reactive to less reactive. 

Amides are the least reactive carboxylic acid derivative, and the only nucleophilic acyl substitution reaction they undergo is hydrolysis. Amides are fairly stable in water, but the amide bond is cleaved on heating in the presence of strong acids or bases. Nominally, this cleavage produces an amine and a car boxylic acid. 

Nitriles are classified as carboxylic acid derivatives because they are converted to carboxylic acids on hydrolysis. The conditions required are similar- to those for the hydrolysis of amides, namely, heating in aqueous acid or base for several hours. Like the hydrolysis of amides, nitrile hydrolysis is ineversible in the presence of acids or bases. Acid hydrolysis yields fflnmonium ion and a carboxylic acid. 

In these papers, the carboxylic acid to be protected was a stable, unsubstituted compound. Harsh conditions were acceptable for both formation and cleavage of the amide. Typically, a simple secondary amide is very difficult to cleave. As the pKa of the conjugate acid of an amide decreases, the rate of hydrolysis of amides derived from these amines increases. The dimethylamide of a cephalosporin was prepared as follows using 2,2 -dipyridyl disulfide. ... 

The chloro atom of 2-[4-(6-chloronicotinoyl)benzyloxy]-3-methyl-4//-pyrido[l,2-n]pyrimidin-4-one, its 6-methyl derivative and 2-[4-(6-chlo-ronicotinoyl)benzylthio]-3-methyl-4//-pyrido[l,2-n]pyrimidin-4-one was replaced by a 4-piperidinopiperidino and 4-phenylpiperazino group with 4-piperidinopiperidine and 4-phenylpiperazine (96EUP733633). The carboxyl group of 2-[4-(4-carboxybenzoyl)benzyloxy]-3-methyl-4//-pyrido[l,2-n]pyrimidin-4-one, prepared by hydrolysis of methyl ester in DMF with 1 N NaOH, was reacted first with diethyl pyrocarbonate in DMF at room temperature and then with 4-phenylpiperazine and 4-piperidinopiperidine to give the appropriate amide derivatives (96EUP733633). 

The result is explained by considering the stacking structure between the quinoline moiety and the benzene ring linked to the carboxylic acid, which gives the cavity size adequate for Li+. (Fig. 3) Several selective host molecules for Li+ such as [13]crown-4 18), [14]crown-4 19), [16]crown-4 20>, or noncyclic polyether amide derivatives 21) also possess trimethylene moiety, and this is an interesting finding from the point of view of molecular design of new host molecules for Li+. 

Closely related to the carboxylic acids and nitriles discussed in the previous chapter are the carboxylic acid derivatives, compounds in which an acyl group is bonded to an electronegative atom or substituent that can net as a leaving group in a substitution reaction. Many kinds of acid derivatives are known, but we ll be concerned primarily with four of the more common ones acid halides, acid anhydrides, esters, and amides. Esters and amides are common in both laboratory and biological chemistry, while acid halides and acid anhydrides are used only in the laboratory. Thioesters and acyl phosphates are encountered primarily in biological chemistry. Note the structural similarity between acid anhydrides and acy) phosphates. 

Electronically, we find that strongly polarized acyl compounds react more readily than less polar ones. Thus, acid chlorides are the most reactive because the electronegative chlorine atom withdraws electrons from the carbonyl carbon, whereas amides are the least reactive. Although subtle, electrostatic potential maps of various carboxylic add derivatives indicate the differences by the relative blueness on the C-O carbons. Acyl phosphates are hard to place on this scale because they are not used in the laboratory, but in biological systems they appear to be somewhat more reactive than thioesters. 

Acid halides are among the most reactive of carboxylic acid derivatives and can be converted into many other kinds of compounds by nucleophilic acyl substitution mechanisms. The halogen can be replaced by -OH to yield an acid, by —OCOR to yield an anhydride, by -OR to yield an ester, or by -NH2 to yield an amide. In addition, the reduction of an acid halide yields a primary alcohol, and reaction with a Grignard reagent yields a tertiary alcohol. Although the reactions we ll be discussing in this section are illustrated only for acid chlorides, similar processes take place with other acid halides. 

Conversion of Amides into Amines Reduction Like other carboxylic acid derivatives, amides can be reduced by LiAlH.4. The product of the reduction, however, is an amine rather than an alcohol. The net effect of an amide reduction reaction is thus the conversion of the amide carbonyl group into a methylene group (C=0 —> CTbV This kind of reaction is specific for amides and does not occur with other carboxylic acid derivatives. 

Carboxylic acids can be transformed into a variety of carboxylic acid derivatives in which the carboxyl -OH group has been replaced by another substituent. Acid halides, acid anhydrides, esters, and amides arc the most common such derivatives in the laboratory thioesters and acyl phosphates are common in biological molecules. 

The most common reactions of carboxylic acid derivatives are substitution by water (hydrolysis) to yield an acid, by an alcohol (alcoholysis) to yield an ester, by an amine (aminolysis) to yield an amide, by hydride ion to yield an alcohol (reduction), and by an organometallic reagent to yield an alcohol (Grignard reaction). 

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