Amides, from acid derivatives acidity

Acid chlorides are often used in these syntheses because they are the most electrophilic of all acid derivatives and because they can be made from the acids themselves with PCI5 or SOCI2. The other important acid derivatives can all be made from acid chlorides or from any compound above them in the chart of reactivity. So you can make amides from acid chlorides, anhydrides or esters but it is very difficult to make any other derivatives from amides. All derivatives except amides can easily be made from the acids themselves. 

No Additional Examples SECTION 77 Amides from Acid Derivatives... 

SECTION 77 AMIDES FROM ACIDS AND ACID DERIVATIVES... 

Carboxylic acid amides from ethylene derivatives G G GH G GON <... 

Carboxylic acid amides from ethylene derivatives... 

Since amides are the least reactive of the carboxylic acid derivatives (shown on the chart above), we can therefore make amides from any carboxylic acid derivatives that are higher on the chart. In other words, we can make amides from acid halides, from anhydrides, or from esters. 

The high reactivity of chlorides is utilized for the preparation of carboxylic acid derivatives by first converting the acids to chlorides and then allowing them to react with amines or alcohols to give suitable derivatives. For the identification of acid chlorides, reactions described on p. 254 are employed. A simple method of preparation of amides from acid chlorides is illustrated by the preparation of stearoylamide. Other useful amines are aniline or p-toluidine the reaction of amines with chlorides is usually carried out by heating the components in an inert solvent (benzene). 

Acid derivatives are made directly from acids or by conversion from other acid derivatives depending on their stabihty. The most important are esters (RCOiEt), amides (RCO2NR2), anhydrides (RCOO COR) and add clilorides (RCOCI). Arrange these in an order of stabilily, the most reactive at the top of the list, the most stable at the bottom. 

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. 

Tetrahydroharman, m.p. 179-80°, has been prepared by a number of workers by a modification of this reaction, viz., by the interaction of tryptamine (3-)5-aminoethylindole) with acetaldehyde or paraldehyde and Hahn et al. have obtained a series of derivatives of tetrahydronorharman by the use of other aldehydes and a-ketonic acids under biological conditions of pH and temperature, while Asahina and Osada, by the action of aromatic acid chlorides on the same amine, have prepared a series of amides from which the corresponding substituted dihydronorharmans have been made by effecting ring closure with phosphorus pentoxide in xylene solution. 

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. ... 

Besides the technical method starting from naphthalene, phthalic acid and its substituted derivatives can be prepared by oxidation of o-xylene to phthalic acid with potassium permanganate. This compound can be subsequently transformed via an anhydride, imide, and amide to a derivative of phthalonitrile, which is the more convenient starting material for several coordination compounds. The synthesis of the ferf-butyl-substituted dicarbonitrile, which is a very common starting material for highly soluble phthalocyanines, is shown below.97,105... 

Amide (35) is made from acid 37) which is derived by elimination from (38), How would you make (38) ... 

Like thallium(I) amide from which it is derived by treatment with potassium amide in liquid ammonia, the ammoniated salt (x = 2 or less) explodes violently on heating, friction, or contact with dilute acids or water. 

The recombinantly expressed nitrilase from Pseudomonas fluorescens EBC 191 (PFNLase) was applied in a study aimed at understanding the selectivity for amide versus acid formation from a series of substituted 2-phenylacetonitriles, including a-methyl, a-chloro, a-hydroxy and a-acetoxy derivatives. Amide formation increased when the a-substituent was electron deficient and was also affected by chirality of the a- stereogenic center for example, 2-chloro-2-phenylacetonitrile afforded 89% amide while mandelonitrile afforded 11% amide from the (R)-enantiomer but 55% amide was formed from the (5)-enantiomer. Relative amounts of amide and carboxylic acid was also subject to pH and temperature effects [87,88]. 

Ester 324 is hydrolyzed to acid 325 by refluxing in 10% NaOH. In a reaction with thionyl chloride, acid 325 is converted to acid chloride 326, which is isolated as a solid in 96% yield and consecutively converted into amide 327 in 85% yield. Treatment of amide 327 with LDA extracts a proton from the methyl group. The generated anion is trapped by added benzonitrile. Subsequent cyclocondensation of the obtained imine anion with the amide group provides derivative 328 in 62% isolated yield (Scheme 50) <2003EJM983>. 

Recently, Borner and coworkers described an efficient Rh-deguphos catalyst for the reductive amination of a-keto acids with benzyl amine. E.e.-values up to 98% were obtained for the reaction of phenyl pyruvic acid and PhCH2COCOOH (entry 4.9), albeit with often incomplete conversion and low TOFs. Similar results were also obtained for several other a-keto acids, and also with ligands such as norphos and chiraphos. An interesting variant for the preparation of a-amino acid derivatives is the one-pot preparation of aromatic a-(N-cyclohexyla-mino) amides from the corresponding aryl iodide, cyclohexylamine under a H2/ CO atmosphere catalyzed by Pd-duphos or Pd-Trost ligands [50]. Yields and ee-values were in the order of 30-50% and 90 >99%, respectively, and a catalyst loading of around 4% was necessary. 

Apart from valpromide derivatives, there are only few other drugs with a primary amide group that undergo metabolic hydrolysis. One example is that of metopimazine (4.23), a phenothiazine with antiemetic properties. Its carboxylic acid 4.24 was the major urinary metabolite in rabbits, but was not formed in dogs [8],... 

Of the methods used for converting amides to aldehydes the one utilizing lithium triethoxyaluminohydride is most universal, can be applied to many types of amides and gives highest yields. In this way it parallels other methods for the preparation of aldehydes from acids or their derivatives (p. 148). 

By analogy with the synthesis of a-hydroxy acids one can envisage a one-pot synthesis of a-hydroxy amides from aldehydes via hydrocyanation and in situ NHase-catalyzed hydrolysis to the amide. Since enantioselective NHases are very rare, the enantioselectivity should be derived from HnL-catalyzed hydrocyanation. The second step has been described for the Rhodococcus erythropolis NHase-catalyzed hydration of (R)-mandelonitrile to give the (R)-amide with retention of enantiopurity [43]. 

In 2001, De Luca and GiacomeUi " reported a new simple and high-yielding one-flask synthesis of Weinreb amides from carboxylic acids and A-protected amino acids that uses different 1,3,5-triazine derivatives (such as 236) as the coupling agents (Scheme 104). The method allows the preparation of Weinreb amides 237 and hydroxamates as O-benzyl and 0-silyl hydroxamates that can be easily transformed into hydroxamic acids. 

AU the products resulting from acid-catalysed solvolysis of A-acetoxy-A-butoxybenz-amides in acetonitrile-water mixtures were derived from the A-butoxy-A-hydroxybenz-amide intermediate (103), which is itself an anomeric amide and is the amide equivalent of a hemi-acetal . Decomposition reactions of 103 under acidic conditions are presented in Scheme 20. 

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