Amides, alkaline hydrolysis

Amides, alkaline hydrolysis, 215 Anharmonic systems, direct evaluation of quantum time-correlation functions, 93 Apollo DSP—160, CHARMM performance, 129/ simulations, solvent effects, 83... 

Amides (except urea and thiourea), imides and nitriles, after the above alkaline hydrolysis, give derivatives similarly to those from the alkaline solution obtained from ammonium salts (p. 360). (A) If the original compound is aromatic, acidification of the cold solution deposits the crystalline acid. (B) The cold solution, when carefully neutralised (p. 332) and treated with benzylthiuronium chloride, deposits the thiuromum salt. 

Note. The treatment of amides with. nitrous add, to obtain the free acid more rapidly than by alkaline hydrolysis, is in general inadvisable when preparing the thiuronium salts.)... 

If the amide is an N-(mono- or di)-substituted amide, or the imide an N-substituted imide, the above alkaline hydrolysis will give a solution... 

The most successful of these products contain high ratios of VP to DMAEMA and are partially quatemized with diethyl sulfate (Polyquaternium 11) (142—144). They afford very hard, clear, lustrous, nonflaking films on the hair that are easily removed by shampooing. More recendy, copolymers with methyl vinyl imidazoliiim chloride (Polyquaternium 16) (145) or MAPTAC (methacrylamidopropyltrimethyl ammonium chloride) (Polyquaternium 28) have been introduced. Replacement of the ester group in DMAEMA with an amide analog as in Polyquaternium 28 results in a resin resistant to alkaline hydrolysis and hence greater utility in alkaline permanent-wave and bleach formulations (see Quaternary ammonium compounds). 

Pyrimido[4,5- f]pyrimidines may be used as pyrimidine precursors. Thus, the dihydro derivative (736) undergoes alkaline hydrolysis to the amide (737 R = PrCO) which may be deacylated in ethanolic hydrogen chloride to give 5-aminomethyl-2-propylpyrimidin-4-amine (737 R = H) (64CPB393) rather similarly, the pyrimidopyrimidinedione (738) reacts with amines to give, for example, 6-amino-5-benzyliminomethyl-l,3-dimethylpyrimidine-2,4(lFf,3Ff)-dione (739 R = CH2Ph) or the hydrazone (739 R = NH2) (74JCS(Pl)1812). 

In fact, most pyrimidinecarboxylic acids are made by hydrolysis of the corresponding esters, nitriles or sometimes amides, many of which can be made more easily by primary synthesis than can the acids themselves. Thus, pyrimidine-5-carboxylic acid may be made by alkaline hydrolysis of its ethyl ester (62JOC2264) and pyrimidin-5-ylacetic acid (789 ... 

Sulfonamides (R2NSO2R ) are prepared from an amine and sulfonyl chloride in the presence of pyridine or aqueous base. The sulfonamide is one of the most stable nitrogen protective groups. Arylsulfonamides are stable to alkaline hydrolysis, and to catalytic reduction they are cleaved by Na/NH3, Na/butanol, sodium naphthalenide, or sodium anthracenide, and by refluxing in acid (48% HBr/cat. phenol). Sulfonamides of less basic amines such as pyrroles and indoles are much easier to cleave than are those of the more basic alkyl amines. In fact, sulfonamides of the less basic amines (pyrroles, indoles, and imidazoles) can be cleaved by basic hydrolysis, which is almost impossible for the alkyl amines. Because of the inherent differences between the aromatic — NH group and simple aliphatic amines, the protection of these compounds (pyrroles, indoles, and imidazoles) will be described in a separate section. One appealing proj>erty of sulfonamides is that the derivatives are more crystalline than amides or carbamates. 

The Willgerodt reaction yields amides 2 as products, while the Willgerodt-Kindler reaction yields N,N-disubstituted thioamides 5. Both types of products can be converted to the corresponding carboxylic acid 6 by alkaline hydrolysis. 

When a carbonyl group is bonded to a substituent group that can potentially depart as a Lewis base, addition of a nucleophile to the carbonyl carbon leads to elimination and the regeneration of a carbon-oxygen double bond. Esters undergo hydrolysis with alkali hydroxides to form alkali metal salts of carboxylic acids and alcohols. Amides undergo hydrolysis with mineral acids to form carboxylic acids and amine salts. Carbamates undergo alkaline hydrolysis to form amines, carbon dioxide, and alcohols. 

An example will show the nature of electrical effects (resonance and field) on reactivity. In the alkaline hydrolysis of aromatic amides (10-11), the rate-determining step is the attack of hydroxide ion at the carbonyl carbon ... 

Hydrolysis may be effected with 10-20 per cent, sodium hydroxide solution (see TolunitrUe and Benzonitrile in Section IV,66) or with 10 per cent, methyl alcoholic sodium hydroxide. For difficult cases, e.g., OL-Naphthonitrile (Section IV.163), a mixture of 50 per cent, sulphuric acid and glacial acetic acid may be used. In alkaline hydrolysis the boiling is continued until no more ammonia is evolved. In acid hydrolysis 2-3 hours boiling is usually sufficient the reaction product is poured into water, and the organic acid is separated from any unchanged nitrile or from amide by means of sodium carbonate solution. The resulting acid is identified as detailed in Section IV,175. 

Substituted amides suffer hydrolysis with greater difficulty. The choice of an acid or an alkaline medium vill depend upon (a) the solubility of the compound in the medium and (b) the effect of the reagent upon the products of hydrolysis. Substituted amides of comparatively low molecular weight (e.g., acetanilide) may be hydrolysed by boiling either with 10 per cent, sodium hydroxide solution or with 10 per cent, sulphuric acid for 2-3 hours. Other substituted amides are so insoluble in water that little reaction occurs when they are refluxed with dilute acid or dilute alkali for several hours. These include such substances as benzanilide (C(H(CONHC,Hg) and the benzoyl derivative of a naphthylamine (C.HjCONHCioH,) or a toluidine (C gCONHCjH,). For these substances satisfactory results may be obtained with 70 per cent, sulphuric acid this hydrolysis medium is a much better solvent for the substituted amide than is water or more dilute acid it also permits a higher reaction temperature (compare Section IV 192) ... 

Simple amides are satisfactory protecting groups only if the rest of the molecule can resist the vigorous acidic or alkaline hydrolysis necessary for removal. For this... 

Formazans are stable in alkaline solution. Alkaline hydrolysis of functionalities on formazans such as nitriles, esters, and amides leads to the acids (Section 7.3.1.1). The case of 3-nitroformazans (198) is unique. Reaction with hydroxide ion gives 3-hydroxy formazan (199) which can be readily oxidized to the tetrazolium betaine. In the presence of hydrosulfide, a reduction of the nitro group takes place giving 3-aminoformazan (200) with traces of the 3-mercaptoformazan (201), which by contrast is the main product when ammonium polysulfide is used (Scheme 30).45,346... 

The nitrogen atoms of the twisted amides discussed on pages 107-108 are to a greater or lesser extent pyramidal, and incipient lone pairs electron density is thus available for reactions with electrophiles. The classic example is the cage lactam [57] first prepared by Pracejus (1959), which has an amide nitrogen with near normal amine basicity. Brown and coworkers have measured rates of alkaline hydrolysis of a series of anilides [58] and [59] with related structures and find that the rate increases with increasing divergence... 

Fig. 12 Dependence of the rate constant for alkaline hydrolysis for three amides [58] (x = 1, y = 2 x = 2, y = 1 and x = y = 2), and [59] on three different geometrical parameters the twist-torsional angle r (A), and the out-of-plane bending at the amide carbonyl (O) and nitrogen ( ) centres. [The geometrical...

Hydrolysis of the methyl ester and decarboxylation at C-18 occur only under forcing conditions. Alkaline hydrolysis of the C-18 ester of vinblastine requires refluxing m 5 N sodium hydroxide for several hours to give the diacid (18), and ammonialysis of this position in anhydrous methanol is accomplished in a sealed vessel at 100°C for 60 hr to yield the 18 -decarbomethoxy-4-deacetylvinblastine amide (19) (55). Bisindole derivatives lacking the C-22 carboxyl have also been prepared by coupling the vindoline portion with an appropriately chosen ibogane precursor (Section V,G) (54). 

Glutethimide Glutethimide, 2-ethyl-2-phenylgutarimide (4.3.6), is synthesized by addition of 2-phenylbutyronitrile to the methylacrylate (Michael reaction), and the subsequent alkaline hydrolysis of the nitrile group in the obtained compound (4.3.5) into an amide group, and the subsequent acidic cycUzation of the product into the desired glutethimide (4.3.6) [38-42]. 

Simple amides are satisfactory protective groups only if the rest of the molecule can resist the vigorous acidic or alkaline hydrolysis necessary for their removal. For this reason, only amides that can be removed under mild conditions have been found useful as amino-protecting groups. Phthalimides are used to protect primary amino groups. The phthalimides can be cleaved by treatment with hydrazine. This reaction proceeds by initial nucleophilic addition at an imide carbonyl, followed by an intramolecular acyl transfer. 

Although no 4-aminoquinolizinium derivatives are known, a benzo derivative, 6-amino-acridizinium ion (72 Scheme 50), has been prepared (67JOC733). In the presence of hydroxide ion the amino group loses a proton to form a benzo[6 ]quinolizin-6-imine (73). Alkaline hydrolysis opens the ring to give the amide (74). 

The alkaline hydrolysis of the l,4-benzodiazepin-2-one (236) and its 4-oxide resulted in ring opening via amide cleavage. Similarly treatment with methylamine gave (246) which proved to be a useful intermediate in the synthesis of the 3-carboxamide (247). 

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