Carboxylic acid amide amides

Hofmann s amine synthesis can be applied to both aliphatic and aromatic carboxylic acid amides, benzamide, C HsCONH, thus giving aniline, C4H5NH,. 

Many compounds contain more than one functional group Prostaglandin Ei a hormone that regulates the relaxation of smooth muscles con tains two different kinds of carbonyl groups Classify each one (aldehyde ketone carboxylic acid ester amide acyl chloride or acid anhydride) Identify the most acidic proton in prostaglandin Ei and use Table 1 7 to estimate its pK ... 

Amino groups bound to sulfur can be replaced by fluorine via diazotization. In contrast to carboxylic acid amides, fluorodediazoniation of aromatic sulfonamides IS readily accomplished to give sulfonyl fluorides in high yields [52, 7S (equation 16) Tetrazotization-fluorination of sulfanilamide can also be effected to give a 38% yield of p-fluorobenzenesulfonyl fluoride [52],... 

H-bond donor/acceptors water, alcohols, carboxylic acids, amines, amides. 

Substances of this type have hitherto received little attention. One of the reasons appears to be the limited possibilities of preparation. The only known method of preparation, described by Woolley et ai./ proceeds from the derivatives of 4-aminoimidazole-5-carboxylic acid. The amide of this acid (142) is treated with nitrous acid to yield 4-hydroxyimidazo [4,5-d]-i -triazine (2-azahypoxanthine) (143), the amidine (144) yielding the 4-amino derivative (2-azaadenine) (145) under the same conditions. 2-Azahypoxanthine was probably obtained in the same way earlier but was not identified. ... 

Bond-Huper [69JCS(C)2453] synthesis, no traces of the described high-melting dark red substance were found. Only tolane-2-carboxylic acid amide (yield 65%) was obtained—the white crystals with a melting temperature of 156-157°C— which coincided with the results of Castro et al. (66JOC4071). Thus, in conditions of acetylide synthesis, o-iodobenzamide forms no bicyclic product. 

Intramolecular addition of the amide group to the triple bond in pyrazoles is more difficult, and results in closure of the 5-lactam rather than the y-lactam ring. The reaction time of the 4-phenylethynylpyrazole-3-carboxylic acid amide under the same conditions is extended to 42 h (Scheme 129) (Table XXVII). The cyclization of l-methyl-4-phenylethynyl-l//-pyrazole-3-carboxylic acid amide, in which the acetylene substituent is located in the 7r-electron-rich position of the heterocycle, is the only one complete after 107 h (Scheme 130) (90IZV2089). 

TABLE XXVn. l-Methyl-l,6-dihydropyrazolo[3,4-c]pyridin-7-ones Prepared by Cyclization of Vicinal 4-(Alkyn- l-yl)pyrazole-5-carboxylic Acid Amides [90IZV2089]. 

Diuretic activity can be retained in the face of replacement of one of the sulfonamide groups by a carboxylic acid or amide. Reaction of the dichlorobenzoic acid, 174, with chlorsulfonic acid gives the sulfonyl chloride, 175 this is then converted to the amide (176). Reaction of that compound with furfuryl ine leads to nucleophilic aromatic displacement of the highly activated chlorine at the 2 position. There is thus obtained the very potent diuretic furosemide (177). ... 

Anhydrides are reduced with relative ease. McAlees and McCrindle 20) established the following increasing order of difficulty for various carbonyls acid chlorides > aldehydes, ketones > anhydrides > esters > carboxylic acids > amides. Reduction may proceed by 1,2-addilion of hydrogen or by cleavage of an oxygen-carbonyl bond. If 1,2-addition to the carbonyl occurs, as in the presence of strong protic acids over palladium, 1,1-diesters are formed by acylation 26). 

Conversion of Amides into Carboxylic Acids Hydrolysis Amides undergo hydrolysis to yield carboxylic acids plus ammonia or an amine on heating in either aqueous acid or aqueous base. The conditions required for amide hydrolysis are more severe than those required for the hydrolysis of add chlorides or esters but the mechanisms are similar. Acidic hydrolysis reaction occurs by nucleophilic addition of water to the protonated amide, followed by transfer of a proton from oxygen to nitrogen to make the nitrogen a better leaving group and subsequent elimination. The steps are reversible, with the equilibrium shifted toward product by protonation of NH3 in the final step. 

Basic hydrolysis occurs by nucleophilic addition of OH- to the amide carbonyl group, followed by elimination of amide ion (-NH2) and subsequent deprotonation of the initially formed carboxylic acid by amide ion. The steps are reversible, with the equilibrium shifted toward product by the final deprotonation of the carboxylic acid. Basic hydrolysis is substantially more difficult than the analogous acid-catalyzed reaction because amide ion is a very poor leaving group, making the elimination step difficult. 

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. 

Sulphoxides with -carboxylic acid or amide groups are converted, in nearly quantitative yields, to the sulphone whilst other acids and amides did not show oxidation. In the cases where oxidation did occur, the acid group was converted to the acid chloride (equation 31) whilst the amide was converted to the nitrile (equation 32). These results indicate that neighbouring-group participation in the case of carboxylic acids and amides occurs only when a five-membered intermediate is formed. In the case of hydroxyl groups, four-, five-or six-membered intermediates are favourable. 

Many procedures for the formation of carboxylic acid amides are known in the literature. The most widely practiced method employs carboxylic acid chlorides as the electrophiles which react with the amine in the presence of an acid scavenger. Despite its wide scope, this protocol suffers from several drawbacks. Most notable are the limited stability of many acid chlorides and the need for hazardous reagents for their preparation (thionyl chloride, oxalyl chloride, phosgene etc.) which release corrosive and volatile by-products. Moreover, almost any other functional group in either reaction partner needs to be protected to ensure chemoselective amide formation.2 The procedure outlined above presents a convenient and catalytic alternative to this standard protocol. 

Recognize a simple haloalkane, alcohol, ether, phenol, aldehyde, ketone, carboxylic acid, amine, amide, or ester, given a molecular structure. 

The tertiary amines 303 and the acid chlorides 304 (X = Cl) initially formed acylammonium salts 305, which underwent a von Braun type degradation by an attack of the nucleophilic chloride ion at the allyl system to give allyl chlorides 306/307 and carboxylic acid amide functions. 

Linkage of Bioactive Molecules that Contain Carboxylic Acid Groups Amide Linkages... 

Section 315 (Carboxylic Acid - Amide). Section 344 (Amide - Ester). 

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