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Addition reactions hydroxylamine synthesis

The first reported synthesis of hydroxyurea (24) consists of the condensation of hy-droxylamine with potassium cyanate (Scheme 7.14) [87]. Condensation of hydroxy-lamine with ethyl carbamate also gives pure hydroxyurea in good yield after recrystallization (Scheme 7.14) [88]. Nitrogen-15 labeled hydroxyurea provides a useful tool for studying the NO-producing reactions of hydroxyurea and can be prepared by the condensation of N-15 labeled hydroxylamine with either potassium cyanate or trimethylsilyl isocyanate followed by silyl group removal (Scheme 7.14) [89, 90]. Addition of hydroxylamine to alkyl or aryl isocyanates yields alkyl or aryl N-hydroxyureas (Scheme 7.14) [91, 92]. The condensation of amines with aromatic N-hydroxy carbamates also produces N-substituted N-hydroxyureas (Scheme 7.14) [93]. [Pg.189]

The successful synthesis of 2-thienyl and substituted 2- and 3-thienyl-acetylenes in yields as high as 60-80% opened a wide variety of synthetic applications. Various addition reactions with carbonyl compounds or epoxides could be carried out with ease. Aliphatic as well as aromatic amine addition reactions, or condensation reactions with hydrazine or hydroxylamine could be easily performed. [Pg.143]

The main first part of the review (Section HI) summarizes preparation of hydroxylamine derivatives through alkylation, arylation, and addition reaction of hydroxylamine, or its derivatives such as hydroxamic acids and A-oxysulfonamides. The second main part (Sections IV-VIII) describes methods of creation of hydroxyamino groups de novo from other functionalities. Due to easy interconversion outlined in Section II, syntheses of hydroxylamines and hydroxamic acids are considered together. For the same reason, the chapter also relates to synthesis of A-oxysulfonamides and V-oxyphosphonamides as far as these methods are of interest for the preparation of hydroxylamines. [Pg.118]

The DRS UV-Vis spectra reported in Figure 8 provide an explanation in the role of Ti center in the hydroxylamine synthesis as well as in the reaction sequence shown in the figure TiS (spectrum 1) reacts with hydrogen peroxide in aqueous solution generating a hydroperoxo species (spectrum 2, complex 2) the addition of ammonia produces a mixed ammonia-hydroperoxo species (spectrum 3, complex 3). In time, ammonia is oxidized to hydroxylamine restoring the Ti center. Spectrum 4 shows the final step of tiie catalytic reaction (7). [Pg.43]

In 1998, Dankwardt used for the first time ester linkers for the synthesis of hydroxamates [116]. The synthesis of hydroxamates and hydroxamic acids is a known synthesis on solid supports but former approaches used special hydroxamate linkers that had to be synthesized in previous reactions. The methodology published by Dankwardt is very simple because ArgoGel-OH resins can be used without further derivatization to bind protected amino acids 88 in the presence of coupling reagents. Hydroxamic acids 90 were cleaved by the addition of hydroxylamine in 21% (sterically hindered amino acids) to quantitative yields (glycin. Scheme 12). [Pg.15]

Earlier reported syntheses have been shown to give isoxazolin-5-ones. Other isoxazolin-3-ones have been prepared by the reaction of methylacetoacetic esters and hydroxylamine. An additional synthesis was reported by the action at 0°C of hydroxylamine on ethyl -benzoylpropionate to produce an insoluble hydroxamic acid which cyclized on acid treatment. The hydroxamic acid acetal was similarly transformed into the isoxazolin-3-one (Scheme 149) (71BSF3664, 70BSF1978). [Pg.106]

The addition of ( )-(3-trimcthylsilylallyl)boronate (10) to the racemic oxime 9 has been used in connection with a total synthesis of cannabisativine n. The results are congruent with the application of ( )-crotylboronatc as organometallic reagent9,, 0. The reaction is anti selective and generates the diastereomeric hydroxylamines 11 and 12, where 11 is converted to a tetrahydropyridine 13, a useful intermediate for the synthesis of cannabisativine11. [Pg.753]

Nitro compounds are versatile precursors for diverse functionalities. Their conversion into carbonyl compounds by the Nef reaction and into amines by reduction are the most widely used processes in organic synthesis using nitro compounds. In addition, dehydration of primary nitro compounds leads to nitrile oxides, a class of reactive 1,3-dipolar reagents. Nitro compounds are also good precursors for various nitrogen derivatives such as nitriles, oximes, hydroxylamines, and imines. These transformations of nitro compounds are well established and are used routinely in organic synthesis. [Pg.159]

Reaction of porphyrins with nitrones has also been studied and the results obtained showed that this is a versatile approach leading to the synthesis of isoxazolidine fused-chlorins (Scheme 26). For instance, chlorin 74 was successfully prepared from the reaction of the jV-methylnitrone, generated in situ from JV-methyl hydroxylamine and paraformaldehyde, with porphyrin Id . It is important to note that bis-addition also took place, yielding exclusively bacteriochlorin type derivatives 76 and 77 (Figure 6). This result contrasts with those obtained in 1,3-DC reactions with azomethinic ylides where isobacteriochlorins were obtained preferentially. [Pg.63]

Addition of Lithiated Sulfoxides and Sulfones Nucleophilic addition of lithiated methylaryl sulfoxides (384) to nitrones of various structures proceeds easily and in good yields (622). The reactions are applied to the synthesis of optically active a-substituted and a,a-disubstituted hydroxylamines, to secondary amines (623), and to enantioselective syntheses of alkaloids (624). The preferred approach to (+ )-euphococcinine is based on the use of homochiral 3-sullinyl nitrones (385) (Scheme 2.167). [Pg.268]

Addition of lithium derivatives of acetylenides (Li—C=C-C02R) to chiral nitrones proceeds with high stereoselectivity, giving a-acetylene substituted hydroxylamines (410a,b) (656). This reaction has been successfully applied to the synthesis of y-hydroxyamino-a, 3-ethylene substituted acids (411a,b), formed in the reduction of (410) with Zn in the presence of acid (657, 658), and to chiral 5-substituted-3-pyrroline-2-ones (412a,b) (Scheme 2.184) (658). [Pg.280]

Complete Synthesis of Succindialdehyde. JACS, 68, 1608 (1946). In a 2 liter 3 necked flask equipped with a stirrer, reflux condenser, and an addition funnel, is mixed 1 liter of ethanol, 67 g of freshly distilled pyrrole, and 141 g of hydroxylamine hydrochloride. Heat to reflux until dissolved, add 106 g of anhydrous sodium carbonate in small portions as fast as reaction will allow. Reflux for 24 hours and filter the mixture. Evaporate the filtrate to dryness under vacuo. Take up the residue in the minimum amount of boiling water, decolorize with carbon, filter and allow to recrystallize in refrigerator. Filter to get product and concentrate to get additional crop. Yield of succinaldoxime powder is a little over 40 g, mp is 171-172°. [Pg.67]

A previous review has highlighted the following methods of ring synthesis intramolecular cyclization of oximes, nitro alkenes, and nitrones, and [4+2] cycloaddition reactions <1996CHEC-II(6)279>. In addition to that, this review includes the intramolecular cyclization of hydroxylamines, hydroxamates, hetero-Diels-Alder [4+2], 1,3-dipolar cycloaddition of nitrile oxides to alkenes, and [3+3] cycloaddition reactions. This review does not cover cycloaddition reactions of the [4+2] [3+2] and [4+2] [3+2] [3+2] types which primarily led to heterocycle-fused oxazine ring systems. [Pg.353]

Isoniazide, the hydrazide of pyridine-4-carboxylic acid, is still, well over half a century after its discovery, one of the mainstays for the treatment of tuberculosis. Widespread use led to the serendipitous discovery of its antidepressant activity. This latter activity is retained when pyridine is replaced by isoxazole. The requisite ester (45-4) is obtained in a single step by condensation of the diketo ester (45-1), obtained by aldol condensation of acetone with diethyl oxalate, with hydroxylamine. One explanation of the outcome of the reaction assumes the hrst step to consist of conjugate addition-elimination of hydroxylamine to the enolized diketone to afford (45-2) an intermediate probably in equilibrium with the enol form (45-3). An ester-amide interchange of the product with hydrazine then affords the corresponding hydrazide (45-5) reductive alkylation with benzaldehyde completes the synthesis of isocarboxazid (45-6) [47]. [Pg.267]


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