Amides reaction with acid derivatives

It is important to reiterate that tertiary amines do not give amides upon reaction with acid derivatives. It is also important to single out two simple amides that are particularly useful formamide (105) and AT,N-dimethylformamide (106 commonly known as DMF). Both are amides derived from formic acid and both are very useful as polar solvents in a variety of reactions. The amide DMF is used as a solvent in many reactions, particularly for the Sn2 reactions in Chapter 11. 

For conversion of amide to other acid derivatives, a novel synthesis of urea glycosides in aqueous media has been reported via the reaction of Steyermark s glucosyl carbamate with amines in good yields (Eq. 9.17).38 This method was successfully applied to develop a new route to the synthesis of urea-tethered neo-glycoconjugates and pseudooligosaccharides. 

Enantiospecific syntheses of amino derivatives of benzo[ ]quinolizidine and indolo[2,3- ]quinolizidine compounds have also been achieved via A-acyliminium ion cyclization reactions, as an alternative to the more traditional Bischler-Napieralski chemistry (see Section 12.01.9.2.2). One interesting example involves the use of L-pyroglutamic acid as a chiral starting material to construct intermediates 240 via reaction with arylethylamine derivatives. Diisobutylaluminium hydride (DIBAL-H) reduction of the amide function in 240 and subsequent cyclization and further reduction afforded piperidine derivatives 241, which stereoselectively cyclized to benzo[ ]quinolizidine 242 upon treatment with boron trifluoride (Scheme 47) <1999JOC9729>. 

The chlorinated intermediate 255 is eliminated and cycloadds to Cjq, yielding pyrazo-linofullerenes of the structure 257 (Scheme 4.42). The 4-nitrophenyl-group can be replaced by a 4-methoxyphenyl- or a phenyl substituent. In this reaction various aromatics and substituted aromatics are tolerated as residues R (e.g. furan, ferrocene, pyrazole or benzene and substituted benzene). The nitro group of the nitrophenyl residue can be reduced with Sn-HCl to the aniline derivative, which can be further functionalized by amide coupling with acid chlorides [311]. 

This chapter deals with the kinetics and mechanisms of the hydrolysis of carboxylic acid derivatives of general formula RCOX. These include carboxylic acid halides, amides, and anhydrides with small sections on carboxylic acid cyanides etc. Many recent developments in this field have been made with acid derivatives in which R is not an aliphatic or aromatic group, for example, carbamic acid derivatives, and these are reported where relevant, as are reactions such as ethanolysis, aminolysis, etc. where they throw light on the mechanisms of hydrolysis. 

Mechanism 21-13 Hydride Reduction of an Ester 1015 Mechanism 21-14 Reduction of an Amide to an Amine 1016 21-9 Reactions of Acid Derivatives with Organometallic Reagents 1017 Mechanism 21-15 Reaction of an Ester with Two Moles of a Grignard Reagent 1018... 

Apart from the reaction with halogen derivatives, use was also made, for the synthesis of silicon-containing cellulose esters, of the reaction of alcoholysis, with cellulose, of tetraalkoxysilanes or alkyl(aryl)trialkoxy-silanes and the amides of siliconic acids (64) ... 

Some of these transformations were accompanied by additional reactions, e.g. formylation of the aromatic or heteroaromatic - nucleus or CH-acidic methyl groups further dehydration of amides to nitriles was observed. Adducts from amides and PCI3, sulfonyl halides or SO2CI2/SCXZI2 from which amidines can be obtained by reaction with amine derivatives (compare Section 2.7.2.5 and refs. 5 and 14) have not found wide application for this purpose. An interesting reaction is the preparation of the amidine (294 equation 158) from 7V-pentafluorophenylformamide. By thermal decomposition of the adducts from secondary amides and 7V,iV-dialkylcarbamoyl chlorides amidinium salts were synthesized from which the amidines (295 equation 159) were set free by treatment with bases. " ... 

Hydrazides are normally made by the reaction of acid derivatives, such as esters, acid chlorides, or amides with hydrazine. The interaction of esters and hydrazine hydrate is very straight-forward and gives good yields. If the esters are liquid, simple addition of hydrazine hydrate to the diethyl ether solution of the esters will cause the precipitation of the hydrazide. If the esters are solid or insoluble, solvents such as methanol or ethanol are required. Normally, such reactions take place very rapidly. Diesters normally form dihydrazides if an excess of hydrazine is used. However, we have been able to convert some diesters into monoester-monohydrazide derivatives (e.g., (94) and (95)) by controlling the molar ratio in a highly diluted reaction (for typical examples see Scheme 23).96... 

The amino group of 4-amino-3-pyrazolin-5-ones reacts normally. Acylation occurs readily with a wide variety of acylating agents. Amides are formed by reaction with acid chlorides,50,533,984,1414,1473 acids618,984,1471 and esters in the presence of phosphorus pentoxide.1471 Thioformamides have been prepared by reaction with dithioformic acid and its salts.472,556,1374 Sulfonyl chlorides react to form sulfonamides.98,489,984,1249,1504 Chlorophosphates react with 4-amino-3-pyrazolin-5-ones to form phosphoramide derivatives.509,1498... 

Kamochi and Kudo have reported the use of the Sml2/THF-H20 system to reduce aromatic carboxylic acids to alcohols (Scheme 50). Furthermore, aromatic esters amides and nitriles were similarly reduced by this system in good yield [104]. As indicated above, reduction of carboxylic acids to primary alcohols is also effective with Sml2 in a THF-H20-NaOH mixture [105]. In contrast, without water these substrates remain unchanged. With the Sml2/THF-H20 system, pyridine was rapidly reduced to piperidine in similar reactions with pyridine derivatives bearing chloro, amino and cyano substituents, these functionalities were partly eliminated to afford pyridine or piperidine [107]. 

At intervals (1 hr), small aliquots (0.2-0.3 mL) of the reaction mixture are withdrawn, acidified with a few drops of coned HCI (35%), and extracted with diethyl ether (2 mL). Then they are analyzed by GC (DB5 capillary column) both the amide and the acid derived from the reacting nitrile are present. After 4.5 hr, the product is 99% acid 3 (2-phenylpropionic acid). The checkers followed the hydrolysis by TLC analysis SiC>2 plates 4 1 hexane ethyl acetate short-wave UV detection R (acid) = 0.43, Rf (amide) = 0.61. 

The acyl substitution reactions associated with acid derivatives are discussed in great detail in Chapter 20. Acid chlorides, anhydrides, esters, and amides all undergo this reaction. Acid chlorides tend to be more reactive than esters because of the greater reactivity of the tetrahedral intermediate. This means that the Cl is a better leaving group when compared to OR. Such differences in leaving group ability are also discussed in Chapter 20. 

When acid derivative 2 reacts with sulfuric acid, the oxygen atom is the base and the conjugate acid product of this acid-base reaction is oxocarbenium ion 3, which is resonance stabilized. When 2 is an acid chloride, anhydride, ester, or amide, a heteroatom is attached to the positive carbon in 3. As in Chapter 18 (Section 18.1), the acid-base reaction of the carbonyl unit in 2 to give 3 facilitates reactions with nucleophiles. The reaction of intermediate 3 with a nucleophile ( Y) gives tetrahedral intermediate 4 contrary to acyl addition, reaction 4 contains an X group that can function as a leaving group. Loss of X leads to the final product of this reaction 5. If the nucleophile ( Y) is hydroxide, compormd 5 is the carboxylic acid (X = OH). If the nucleophile Y is an alcohol, the product 5 is an ester, and if Y is an amine, the product 5 is an amide. This first reaction is therefore the acid-catalyzed acyl substitution reaction of acid derivatives. 

The other significant variation of the prototypical Kulinkovich reaction is the so-called Kulinkovich-de Meijere reaction, where de Meijere extended the substrates from esters to amides. Other carboxylic acid derivatives including (cyclic) carbonate, imides, and nitriles also react with the key Kulinkovich intermediate. Szymoniak developed an efficient new synthesis of cyclopropanes via hydrozirconation of allylic ethers (e.g., using Cp2Zr(H)Cl) followed by addition of a Lewis acid (e.g., BFa OEta). Casey et al. further investigated the stereochemistry of this interesting cyclopropanation reaction using deuterated allylic ethers. ... 

Based on lysine as before, single chain derivatives (18) and bicatenar compounds (19) have been prepared by a strategy the inverse of that described earlier [46]. The products (18 and 19) are obtained with higher overall yields than 17. As before, no protection or deprotection steps are needed in this case [46,47]. The synthesis consists of a reaction between two moduU prepared beforehand, one representing the polar head group in the final product and the other the junction modulus. The preparation of this intermediate starts from aldoses or acids derived Irom them that are coupled with lysine in its basic form (Scheme 15). The yields for this step are quantitative. A subsequent amidation reaction with a hydrogenated or perfluorinated fatty acid (Scheme 16) leads to the monosubstituted compounds (18). Esterification of the free acid function of lysine (Scheme 17) yields in a final step the bicatenar structures (19). 

Keteniminium salts undergo [2-1-2] cycloaddition reactions with unreactive olefins, such as ethylene, cyclopentene, cyclohexene and styrol to give cyclobutane ammonium salts 23, which are readily hydrolyzed to give cyclobutanones 24. Likewise, reaction with acetylene derivatives affords cyclobutenylidene ammonium salts 25, which are also readily hydrolyzed to give the cyclobutenones 26. Some of the [2-1-2] cycloadducts obtained from keteniminium salts and olefines are shown in Table 4.17. The keteniminium salts are easily synthesized from suitable dimethylamides and phosgene, or trifluoromethanesulfonic acid anhydride. The reaction of the amide with phosgene generates a chloro compound 21, which is in equilibrium with the ketenimine salt 22. 

The reaction with hydroxylamine, leading to hydroxamic acids, takes place less well with amides than with other derivatives of carboxylic adds. It must be carried out at elevated temperatures, for example, in propylene glycol (58, 59). The detection can be carried out in two ways ... 

The imides, primaiy and secondary nitro compounds, oximes and sulphon amides of Solubility Group III are weakly acidic nitrogen compounds they cannot be titrated satisfactorily with a standard alkaU nor do they exhibit the reactions characteristic of phenols. The neutral nitrogen compounds of Solubility Group VII include tertiary nitro compounds amides (simple and substituted) derivatives of aldehydes and ketones (hydrazones, semlcarb-azones, ete.) nitriles nitroso, azo, hydrazo and other Intermediate reduction products of aromatic nitro compounds. All the above nitrogen compounds, and also the sulphonamides of Solubility Group VII, respond, with few exceptions, to the same classification reactions (reduction and hydrolysis) and hence will be considered together. 

The amide group is readily hydrolyzed to acrylic acid, and this reaction is kinetically faster in base than in acid solutions (5,32,33). However, hydrolysis of N-alkyl derivatives proceeds at slower rates. The presence of an electron-with-drawing group on nitrogen not only facilitates hydrolysis but also affects the polymerization behavior of these derivatives (34,35). With concentrated sulfuric acid, acrylamide forms acrylamide sulfate salt, the intermediate of the former sulfuric acid process for producing acrylamide commercially. Further reaction of the salt with alcohols produces acrylate esters (5). In strongly alkaline anhydrous solutions a potassium salt can be formed by reaction with potassium / /-butoxide in tert-huty alcohol at room temperature (36). 

A variety of a-amino acid derivatives, including the acids themselves, haUdes, esters, and amides can be transformed iato hydantoias by coadeasatioa with urea (67). a-Hydroxy acids and thek nitriles give a similar reaction (68) ... 

Acetoiicetyliition Reactions. The best known and commercially most important reaction of diketene is the aceto acetylation of nucleophiles to give derivatives of acetoacetic acid (Fig. 2) (1,5,6). A wide variety of substances with acidic hydrogens can be acetoacetylated. This includes alcohols, amines, phenols, thiols, carboxyHc acids, amides, ureas, thioureas, urethanes, and sulfonamides. Where more than one functional group is present, ring closure often follows aceto acetylation, giving access to a variety of heterocycHc compounds. These reactions often require catalysts in the form of tertiary amines, acids, and mercury salts. Acetoacetate esters and acetoacetamides are the most important industrial intermediates prepared from diketene. 

Amidation. Reaction of maleic anhydride or its isomeric acids with ammonia [7664-41-7] (qv), primary amines (qv), and secondary amines produces mono- or diamides. The monoamide derivative from the reaction of ammonia and maleic anhydride is called maleamic acid [557-24-4] (8). Another monoamide derivative formed from the reaction of aniline [62-53-3] and maleic anhydride is maleanilic acid [555-59-9] (9). 

Introduction of the cobalt atom into the corrin ring is preceeded by conversion of hydrogenobyrinic acid to the diamide (34). The resultant cobalt(II) complex (35) is reduced to the cobalt(I) complex (36) prior to adenosylation to adenosylcobyrinic acid i7,i -diamide (37). Four of the six remaining carboxyhc acids are converted to primary amides (adenosylcobyric acid) (38) and the other amidated with (R)-l-amino-2-propanol to provide adenosylcobinamide (39). Completion of the nucleotide loop involves conversion to the monophosphate followed by reaction with guanosyl triphosphate to give diphosphate (40). Reaction with a-ribazole 5 -phosphate, derived biosyntheticaHy in several steps from riboflavin, and dephosphorylation completes the synthesis. 

Polymerization of castor od, chemical or oxidative, results in higher viscosity or bodied ods that are more usehd in urethane coatings than the untreated castor od (87). Other castor derivatives used to prepare urethanes are amides prepared by reaction of castor od and alkanolamines, amides of ricinoleic acid with long-chain di- and triamines, and butanediol diricinoleate (88,89). 

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. 

Acid chlorides are useful reagents, but when the pyrazole is N- unsubstituted a dimerization occurs and the diketopiperazine (254) is isolated (Section 4.04.2.3.3(x)). However, (254) reacts with many compounds as an acid chloride would, for example with amines to yield amides (67HC(22)l). The difunctional pyrazole derivative (441) affords polymers by reaction with diphenols (69RRC763). Cyanopyrazoles can be hydrolyzed to the corresponding carboxylic acids (68CB829). 

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