Aziridine reaction number

More recently, Tardella and co-workers reported that treatment of 2-trifluorome-thyl acrylate 36 (Scheme 3.12) with the anion generated from nosyloxycarbamate 37 gave rise to aziridine-2-carboxylate 38 in 96% yield and 72% de with undetermined stereochemistry [40]. Aza-MIRC (Michael-initiated ring closure) was used to account for this transformation. A number of other hydroxylamine derivatives have been employed successfully in this type of aziridination reaction, includ-... 

A number of other bis(oxazolines) have been applied as ligands in the copper-catalyzed aziridination reaction. Knight and co-workers (80) examined tartrate-derived ligands. Diastereomeric bis(oxazolines) 110 and 111 were each found to be poorly effective in mediating the asymmetric aziridination of styrene, Eq. 63. 

Che has reported that both achiral and chiral rhodium catalysts function competently for intramolecular aziridination reactions of alkyl- and arylsulfonamides (Scheme 17.29) [59, 97]. Cyclized products 87 are isolated in 90% yield using 2 mol% catalyst, PhI(OAc)2, and AI2O3. Notably, reactions of this type can be performed with catalyst loadings as low as 0.02 mol% and display turnover numbers in excess of 1300. In addition, a number of chiral dimeric rhodium systems have been examined for this process, with some encouraging results. To date, the best data are obtained using Doyle s Rh2(MEOX)4 complex. At 10 mol% catalyst and with a slight excess of Phl=0, the iso-... 

Asymmetric aziridination can also be accomplished via chiral salen ligands. Shi has synthesized a number of axially dissymmetric binaphthyldiimine salen complexes that have shown excellent facility in catalytic asymmetric aziridination reactions <2001TA3105>. Although yields were generally good with acyclic electron-deficient olefins, the chemical yield with electron-rich olefin indene was relatively low (25%). A reasonable enantiomeric excess of 73% was achieved at —20°C over a 24h reaction period (Equation 9). 

Substituted 2-haloaziridines are also known to undergo a number of reactions without ring opening. For example, displacement of chlorine in (264) with various nucleophilic reagents has been found to occur with overall inversion of stereochemistry about the aziridine ring (65JA4538). The displacements followed first order kinetics and faster rates were noted for (264 R = Me) than for (264 R = H). The observed inversion was ascribed to either ion pairing and/or stereoselectivity. 

A number of 2-acylazetidines have been prepared by reaction of 1,3-dihaloacyl compounds with amino derivatives (Section 5.09.2.3.l(m)). This is illustrated for azetidine 2-carboxylic acid (56), the only known naturally occurring azetidine. Ring expansion of activated aziridines (43) and contraction of 4-oxazolines (55) has also found limited use (Section 5.09.2.3.2(f) and Hi)). 

The photolytic and thermolytic decomposition of azides in the presence of olefins has been applied to aziridine synthesis. However, only a limited number of steroid aziridines have been prepared in this manner. The patent literature reports the use of cyanogen azide at ca. 50° for 24 hours in ethyl acetate for the preparation of an A-nor- and a B-norsteroidal aziridine. The addition is believed to proceed via a triazoline. The reaction of cholest-2-ene with ethyl azidoformate takes place in a nonselective manner to produce a mixture of substances, including C—H insertion products. 

The present authors have found that the preparation of 7V-acetyl aziridine derivates provides the most secure method of differentiating aziridines from primary amines which are alternate reaction products in a number of cases. The infrared spectra of the former derivatives show only a peak at 1690 cm" for a tertiary amide peaks at ca. 3440 and 1530 cm" indicative of a secondary amide are absent. Acetylation also shifts the aziridine ring protons to a lower field in the NMR by ca. 1 ppm relative to the parent aziridine. The A"-acetyl aziridines are hydrolyzed with 3% methanolic potassium hydroxide. " Published NMR spectra of several 16j5,17j -aziridines reveal resonance patterns resembling those of the respective epoxides. " ... 

Chiral Mn111porphyrin (55) catalyzes the aziridination of styrene derivatives in the presence of PhI=NTs. Though enantioselectivity is moderate, the turnover number of the catalyst is high (Scheme 40).164 A MnIV—PhINTs adduct (56) has been proposed as the active intermediate for this reaction, on the basis of UV-vis and EPR analyses. 

Epoxides have been found to cleanly react with acetic anhydride to provide the diacetate under solvent-free conditions <06TL6865>. Treatment of epoxides with ammonium-12-molybdophosphate and a slight excess of acetic anhydride (1.2 equivalents) provides the corresponding diacetate in excellent yields. A number of epoxides were examined and all worked quite well. It was also found that /V-losyl aziridines participate in this reaction providing the corresponding acetoxysulfonamides. 

Millar and co-workers studied the reaction of dinitrogen pentoxide in chlorinated solvents with a number of different A-substituted aziridines and found that reactions are highly dependent on the nature of the A-substituent on the aziridine nitrogen (Table 5.9). A-Alkylaziridines give good yields of 1,2-nitramine-nitrate product (Table 5.9, Entry 1). These... 

Aziridines represent an important class of building block within synthesis. This structural motif is also embedded within a number of biologically significant natural products, and thus robust and efficient methods for their construction represent an important contribution to the synthetic toolkit. Cordova reported an enantiose-lective aziridination of a,P-unsaturated aldehydes catalysed by diarylprolinol ether 30 using protected hydroxylamine 91 as the nitrogen source (Scheme 38) [150]. The reaction was proposed to proceed via iminium ion formation followed by... 

There are a few reports on the use of oximes as electrophilic amination reagents. Since 1984, ketone O-sulfonyloxknes have found applicability as amino transfer reagents to car-banions. In the reaction of organometaUic compounds with oximes, carbanions attack the carbonyl carbon of the oxime, giving Af-substituted hydroxylamines as addition products (Scheme 53, path a). However, a number of scattered reports have been also published on the formation of aziridines by a-deprotonation, followed by addition (path b) or formation of azirines by a-deprotonation before addition (path c). Addition of carbanions to azirines also yields aziridines, which are hydrolyzed to a-aminoalcohols. 

Aziridines can undergo loss of a nitrogen atom in a number of ways and this process is frequently stereospecific in terms of the alkene formed. For example, the reaction of aziridines, e.g. (268), with nitrosating agents such as nitrosyl chloride or methyl nitrite results in the formation of alkenes wit.h greater than 99% stereoselective deamination (64JOC1316). Such transformations proceed via N- nitrosoaziridine intermediates which are isolable at temperatures below -20 °C, but which decompose to the observed products at higher temperatures. 

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