With hydroxylamine

As esters are usually difficult to detect, this test is of considerable value. In general esters react when heated with hydroxylamine to give a hydroxamic acid (I). The latter gives a coloured complex (II) with ferric salts in acid solution. 

L. Treat with hydroxylamine and ferric chloride (pp. 334, 353). Violet or red colorations given particularly by esters. Deep colorations also given by acid chlorides, acid anhydrides and by some acid amides (usually aliphatic) and by a few of the simpler anilides. 

The initial product, nitrosobenzene, is so easily reduced to p-phenylhydroxyl-amine that it has never been isolated in the free state, but its presence has been established by reaction in solution with hydroxylamine to 3deld a phenyldi-azonium salt, which couples readily with a a-naphthylamine to form the dyestuff phenyl-azo-a-naphthylamine (compare Section IV,77) ... 

Benzaldehyde reacts with hydroxylamine in the presence of excess of sodium hydroxide to 3deld an oxime of low m.p. (a- or. gjM-benzaldoxime) which is stable to alkah, but is rapidly rearranged by acids to give an isomeric oxime of higha m.p. ( 3- or < i/r-benzaldoxlme) ... 

Bfflizophenone condenses with hydroxylamine hydrochloride in the presence of excess of sodium hydroxide solution to 3deld benzophenone oxime, m.p. 142° ... 

The diacetyl monoxime condenses readily with hydroxylamine hydrochloride or sulphate with the formation of dimethylglyoxime (diacetyl dioxime) ... 

Lactones, which may be regarded as cyclic or inner esters, react similarly. Anhydrides of carboxylic acids also react with hydroxylamine to form hydroxamic acids ... 

R. Mellon (19) but using anhydrous reagents. He obtained an oil that reacted exothermically with hydroxylamine (oxime of m.p. 135°) and that isomerized to 2-oxy-4-methylthiazole (14) upon heating with diluted hydrochloric acid. The thiazolic nature of oxymethylthiazole was clearly demonstrated by its reduction by zinc powder distillation into 4-methylthiazole (23), the first free thiazole ever described. 

The purity of a synthetic preparation of methylethyl ketone (C4H8O) can be determined by reacting the ketone with hydroxylamine hydrochloride, liberating HCl (see Table 9.10). In a typical analysis, a 3.00-mL sample was diluted to 50.00 ml and treated with an excess of hydroxylamine hydrochloride. The liberated HCl was titrated with 0.9989 M NaOH, requiring 32.68 ml to reach the end point. Report the percent purity of the sample, given that the density of methylethyl ketone is 0.805 g/mL. 

In current industrial practice gas chromatographic analysis (glc) is used for quahty control. The impurities, mainly a small amount of water (by Kad-Fischer) and some organic trace constituents (by glc), are deterrnined quantitatively, and the balance to 100% is taken as the acetone content. Compliance to specified ranges of individual impurities can also be assured by this analysis. The gas chromatographic method is accurately correlated to any other tests specified for the assay of acetone in the product. Contract specification tests are performed on product to be shipped. Typical wet methods for the deterrnination of acetone are acidimetry (49), titration of the Hberated hydrochloric acid after treating the acetone with hydroxylamine hydrochloride and iodimetry (50), titrating the excess of iodine after treating the acetone with iodine and base (iodoform reaction). 

This reaction, conducted in alkaline solution, also produces carboxyl groups by hydrolysis of the amide (54). Recent work on the reaction of polyacrylamide with hydroxylamine indicates that maximum conversion to the hydroxamate fiinctionahty (—CONHOH) takes place at a pH > 12 (57). Apparendy, this reaction of hydroxylamine at high pH, where it is a free base, is faster than the hydrolysis of the amide by hydroxide ion. Previous studies on the reaction of hydroxylamine with low molecular weight amides indicated that a pH about 6.5 was optimum (55). 

Reactions with Amines and Amides. Hydroxybenzaldehydes undergo the normal reactions with aUphatic and aromatic primary amines to form imines and Schiff bases reaction with hydroxylamine gives an oxime, reaction with hydrazines gives hydrazones, and reactions with semicarbazide give semicarbazones. The reaction of 4-hydroxybenzaldehyde with hydroxylamine hydrochloride is a convenient method for the preparation of 4-cyanophenol (52,53). 

The assay method involves the reaction of benzaldehyde with hydroxylamine hydrochloride in an alcohoHc solution. Benzaldehyde oxime, water, and hydrochloric acid are the products of the reaction. The hydrochloric acid formed is then titrated with standard caustic solution to determine the benzaldehyde assay. 

Cyclohexanone purity is most readily deteanined by gas-Hquid chromatography over DC-710 or carbowax 20M-on-chromosorb. Impurities such as cyclohexane, ben2ene, cyclohexanol, and phenol do not interfere. In the absence of other carbonyl compounds cyclohexanone may be deterrnined by treatment with hydroxylamine hydrochloride, which forms the oxime, as follows ... 

The chemical consequences of /3-protonation are illustrated further by the ring-opening reactions of furans with methanolic hydrogen chloride and of (V-substituted pyrroles with hydroxylamine hydrochloride (Scheme 11) (82CC800). 

The most useful general method for the C-acylation of pyrroles is the Vilsmeier-Haack procedure in which pyrrole is treated with the phosphoryl chloride complex (55a, b) of an AiA-dialkylamide (54). The intermediate imine salt (56) is hydrolyzed subsequently under mildly alkaline conditions to give the acylated pyrrole (57). On treatment of the imminium salt (56 R =H) with hydroxylamine hydrochloride and one equivalent of pyridine and heating in DMF, 2-cyanopyrrole (58) is formed (80CJC409). 

Amination at an azole ring nitrogen is known for Af-unsubstituted azoles. Thus 4,5-diphenyl-1,2,3-triazole with hydroxylamine-O-sulfonic acid gives approximately equal amounts of the 1- (104) and 2-amino derivatives (105) (74AHC(16)33). Pyrazole affords (106) and indazole gives comparable amounts of the 1- and 2-amino derivatives. 

Scheme 4 also represents the classical route to isoxazoles, first studied in 1888 by Claisen and his coworkers (1888CB1149). Reaction of a 1,3-diketone with hydroxylamine gives, via the isolable monoxime (108) and the 4-hydroxyisoxazole (109), the isoxazole (110). Unsym-metrical 1,3-diketones result in both possible isomers (110) and (111), but the ratio of the isomeric products can be controlled by the right combination of the 1,3-dicarbonyl component and the reaction conditions used. These important considerations are described in Chapter 4.16, along with the variations possible in the 1,3-dicarbonyl component designed to yield diverse substituents in the resultant isoxazole. 

The imonium salt (199), obtained from ynamines and phosgeneimonium chloVide, underwent ready reaction with monosubstituted hydrazines to give the 3,5-bis(dimethyl-amino)pyrazole (200) (68T4217, 69T3453). Similarly, the adduct (201), resulting from the addition of phosgene to ynamines, likewise reacted with sym-disubstituted hydrazines to give pyrazoles (202). With hydroxylamine derivatives the isoxazolinone (203) was obtained. 

To form a five-membered ring in this manner, the 1,3-bielectrophile must contain a heteroatom, and several systems such as the aza analog of (204) are known (68T4217,69T3453). Dimethyl AA-ethoxycarbonylthiocarbonimidate (209) reacted readily with a monosubstituted hydrazine to give the 1,2,4-triazolinone (210), and with hydroxylamine the 1,2,4-oxadiazolinone (211) was obtained (73JCS(P1)2644). 

Azetidines under analogous reaction conditions to those above result in six-membered ring formation. However, diketene (472), an oxetan-2-one, offers considerable promise for five-membered heterocycle formation. With hydroxylamine the 3-methylisoxazolin-5-one (473) was formed. Phenylhydrazine gave the corresponding 3-methyl-l-phenylpyrazolin-5-one. 

The isoxazoles (585) were formed regioselectively from the (dioxoalkyl)phosphonium salts (584) with hydroxylamine hydrochloride, the direction of cyclization being different from that of the nonphosphorus-containing 1,3-dioxo compound (see Chapter 4.16). Aqueous sodium hydroxide converted (585) into the isoxazole (586) and triphenylphosphine oxide. Treatment of (585) with n-butyllithium and an aldehyde gave the alkene (587). With hydrazine or phenylhydrazine analogous pyrazoles were formed (80CB2852). 

N-Amination of indazole affords a mixture of 60% (271) and 40% (272), which compares with the 55 45 ratio obtained in methylation (Section 4.04.2.1.3(viii)). A camphopyrazole derivative (a mixture of tautomers 275 and 276) when treated with hydroxylamine O-sulfonic acid yields exclusively the (4S,7i )-4,7-methano-2-amino-7,8,8-trimethyl-4,5,6,7-tetrahydro-2H-indazole (277) (79YZ699). 

In theory, three isoxazolines are capable of existence 2-isoxazoline (2), 3-isoxazoline and 4-isoxazoline. The position of the double bond may also be designated by the use of the prefix A with an appropriate numerical superscript. Of these only the 2-isoxazolines have been investigated in any detail. The preparation of the first isoxazoline, 3,5-diphenyl-2-isoxazoline, from the reaction of )3-chloro-)3-phenylpropiophenone with hydroxylamine was reported in 1895 (1895CB957). Two major syntheses of 2-isoxazolines are the cycloaddition of nitrile A-oxides to alkenes and the reaction of a,/3-unsaturated ketones with hydroxylamine. Since 2-isoxazolines are readily oxidized to isoxazoles and possess some of the unique properties of isoxazoles, they also serve as key intermediates for the synthesis of other heterocycles and natural products. 

In 1888 Claisen (1888CB1149) first recognized a general synthesis of isoxazoles (283) by the condensation-cyclization of 1,3-diketones (280) with hydroxylamine. It is now generally accepted that the monoxime (281) of the 1,3-diketone and the subsequent 5-hydroxy-isoxazoline (282) are the intermediate products of the reaction. The isolation of the monoxime (281) and 5-hydroxyisoxazoline (282), which were both readily converted into the isoxazole (283) by treatment with acid or base, has been reported (62HC(17)l). 

It was soon found that the reaction of unsymmetrtcal 1,3-diketones (290) or their derivatives with hydroxylamine results in both possible isomeric isoxazoles (291) and (292), a complication which not only reduces the yield of desired product but also often leads to separation problems, particularly when R and R are similar. However, the reaction does give one isomer, or predominantly one isomer, if the right combination of the CCC... 

The reaction of the steroidal )3-ketoaldehyde (293) with hydroxylamine hydrochloride in acetic acid gave a mixture of the 3- and 5-substituted isoxazoles (294) and (295a). In sodium acetate buffer the reaction provided exclusively the 5-substituted isomer (29Sb) (66JOC3193). 

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