Hydroxamic acids rearrangement reactions

If primary or secondary amines are used, A/-substituted amides are formed. This reaction is called aminolysis. Hydra2ines yield the corresponding hydra2ides, which can then be treated with nitrous acid to form the a2ides used in the Curtius rearrangement. Hydroxylamines give hydroxamic acids. 

The hydroxamic acid function in most alicyclic and aromatic compounds is stable to hot dilute acid or alkali, and derivatives cannot undergo normal base-catalyzed Lessen rearrangement. Di Maio and Tardella," however, have shown that some alicyclic hydroxamic acids when treated with polyphosphoric acid (PPA) at 176°-195° undergo loss of CO, CO.2, or H2O, in a series of reactions which must involve earlj fission of the N—0 bond, presumably in a phosphoryl-ated intermediate. Thus, l-hydroxy-2- piperidone(108) gave carbon monoxide, 1-pyrroline (119), and the lactams (120 and 121). The saturated lactam is believed to be derived from disproportionation of the unsaturated lactam. 

In the Lossen reaction a hydroxamic acid derivative (usually an 0-acyl derivative) is deprotonated by base, and rearranges via migration of the group R to give an isocyanate 2. Under the usual reaction conditions—i.e. aqueous alkaline solution—the isocyanate reacts further to yield the amine 3. The Lossen reaction is closely related to the Hofmann rearrangement and the Curtins reaction. 

The 0-acyl derivatives of hydroxamic acids give isocyanates when treated with bases or sometimes even just on heating, in a reaction known as the Lossen rearrangement. The mechanism is similar to that of 18-13 and 18-14 ... 

The Lossen rearrangement of an hydroxamic acid under basic conditions is a variant of the Hofmann reaction in which the aroyloxy group fills the role of the bromine.314... 

Aldehyde 54 and the hydroxamic acids 55 were generated together in an acid-catalysed elimination reaction (Scheme 7 pathway (ii)). A crossover experiment indicated that esters are formed in a concerted rearrangement concomitant with the likely formation of the hydroxynitrene 57 (Scheme 7 pathway (iii)) while there is no evidence to date for the formation of hydroxynitrene, joint solvolysis of equimolar quantities of /V-acetoxy-/V-butoxy-/>-chlorobenzamide 26e and N- acetoxy-/V-benzyloxybenzamide 27a afforded significant quantities of butyl p-chlorobenzo-ate (36%) and benzyl benzoate (54%) as the only esters. This is an example of a HERON reaction, which has been identified in these laboratories as a characteristic rearrangement of bisheteroatom-substituted amides.32,33,42 43 155 158 Since ester formation was shown to prevail in neutral or low acid concentrations, it could involve the conjugate anion of the hydroxamic acid (vide infra).158... 

Nitrosobenzenes react with the carbonyl group of aldehydes to yield hydroxamic acids 73, according to reaction 20. Recently, the reactions between some X-substituted nitrosobenzenes (X = H, p-Me, p-C 1, m-Cl, p-Br) and formaldehyde were reported194 in order to investigate the mechanism of the hydroxamic acid formation. The mechanism reported in Scheme 9 involves a first equilibrium yielding the zwitterionic intermediate 74 which rearranges (by acid catalysis) into hydroxamic acid 75. The presence of a general acid catalysis, the substituent effect (p values of the Hammett equation equal —1.74),... 

Rearrangement reactions of hydroxylamines (1), oximes (2) and hydroxamic acids (3) will be covered in this chapter with emphasis on the developments made during the last 15 years. All referred compounds possess a relatively low energy N—O bond ca 53 kcalmol" ) which facilitates the ability of these compounds to rearrange. 

Rearrangements of hydroxylamines, oximes and hydroxamic acids 441 Thiazoloazepines 402 may be produced by a ring-expansion reaction (equation 165). 

The most widely used rearrangement reactions of hydroxylamine, oximes and hydroxamic acids are reported in previous sections of this chapter, but there are other relevant rearrangements which were less exploited. 

The conversion of hydroxamic acids 589 to a, S-unsaturated amides 592 reported by Hoffmagn and Madan appears to be a first-order reaction of bis-anion 590 characterized by an intramolecular proton rearrangement to one of the anionic oxygen atoms to give conjugated ion 591 (equation 260). 

In 1984 Gassman and Granrud, and Novak and co-workers, published their results on reactions of similar esters of hydroxamic acids. Gassman and Granrud showed that the rearrangement of the methanesulfonate esters 45a-g in CDCI3 (Scheme 23) occurred in a first-order fashion and that kobs correlated with with a slope,, of -9.2. Novak and co-workers showed that the pH-independent first-order rate constants for hydrolysis in 5 vol%... 

The mechanism of Scheme 34 quantitatively explains the yields of rearrangement, solvent-derived and N3-derived products of hydrolysis of hydroxylamine or hydroxamic acid esters that yield selective nitrenium ions (log 5 One of the characteristics of these hydrolysis reactions is the... 

The cyclohexene 121, which was readily accessible from the Diels-Alder reaction of methyl hexa-3,5-dienoate and 3,4-methylenedioxy-(3-nitrostyrene (108), served as the starting point for another formal total synthesis of ( )-lycorine (1) (Scheme 11) (113). In the event dissolving metal reduction of 121 with zinc followed by reduction of the intermediate cyclic hydroxamic acid with lithium diethoxyaluminum hydride provided the secondary amine 122. Transformation of 122 to the tetracyclic lactam 123 was achieved by sequential treatment with ethyl chloroformate and Bischler-Napieralski cyclization of the resulting carbamate with phosphorus oxychloride. Since attempts to effect cleanly the direct allylic oxidation of 123 to provide an intermediate suitable for subsequent elaboration to ( )-lycorine (1) were unsuccessful, a stepwise protocol was devised. Namely, addition of phenylselenyl bromide to 123 in acetic acid followed by hydrolysis of the intermediate acetates gave a mixture of two hydroxy se-lenides. Oxidative elimination of phenylselenous acid from the minor product afforded the allylic alcohol 124, whereas the major hydroxy selenide was resistant to oxidation and elimination. When 124 was treated with a small amount of acetic anhydride and sulfuric acid in acetic acid, the main product was the rearranged acetate 67, which had been previously converted to ( )-lycorine (108). 

H)-Oxazolones are formed by the spontaneous cyclization of /3-oxo isocyanates (equation 134). Similarly, o-hydroxyphenyl isocyanate, produced by the Curtius rearrangement of the azide of salicylic acid or by the action of sodium hypochlorite on salicylamide, forms benzoxazolone (equation 135). An analogous reaction is the formation of IV-phenyl-benzoxazolone by the action of thionyl chloride on the hydroxamic acid shown in equation (136) (78TL2325). Pyrolysis of aryl azidoformates affords benzoxazolones by nitrene insertion (equation 137) (81CC241). 

Azine approach. DCC dehydration of the 3-oxoquinazoline-4-hydroxamic acid (602) gives an isocyanate (603) via a Lossen rearrangement addition of the AT-oxide oxygen to the isocyanate group effects the cyclization. The same product is formed by the phosgene reaction with 4-amino-2-methylquinazoline 3-oxide (76TL3615). 

A new synthesis of ( )-crinane (13) (Scheme 2) may be applicable to Amaryllidaceae alkaloids.5 Key features of the synthesis are the preparation of the acid (10) by Claisen rearrangement of the allylic acetate (9) and intramolecular ene reaction of a protected acylnitroso-enophile (11) to give the cyclic hydroxamic acid (12). 

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