A-alkyl oxaziridine

The reaction of 2-isopropyl-5,5-dimethyl-5,6-dihydro-2//-l,3-oxazine 306 with MCPBA leads to formation of the corresponding A -alkyl oxaziridine 307 as a single isomer <1995T139>. Due to the preferential conformation of imine 306, the imine double bond is exclusively oxidized anti to the f-propyl moiety. Oxidation of imine 308 with MCPBA gave oxaziridine nitroxide 309 in 90% yield <2000TL8787> and similar oxidation of 310 gave oxaziridine 311 in 74% yield <2005S1496>. 

Treatment of imine 331 with KHSOs (Oxone) in the presence of NaHC03 afforded A -alkyl oxaziridines 332 in 67-85% yields (Table 26) <2005JOC301>. Optically active oxaziridines of this type could be obtained using phenyl ethylamine as the chiral directing group (Table 26, entries 3 and 4). 

The oxidation of chiral imines with peracids and the oxidation of achiral imines with chiral peracids to give optically active A-alkyl oxaziridines has been reviewed <84MI 112-01 >. The resolution of chiral A-alkyloxaziridine-3,3-dicarboxylic esters through the enzymatic hydrolysis of the racemic diesters, in moderate ees, has been reported <88CC1614>. 

Methylenenitrones (293) are obtained from nitrosoalkanes and diazomethane, and on irradiation they gave A -alkyl oxaziridines (294) in near quantitative yield. 

X-ray analysis of an optically active oxaziridine substituted at nitrogen with the 1-phenylethyl group of known configuration led to the absolute configuration (+)-(2R,3R)-2-(5-l-phenylethyl)-3-(p-bromophenyl)oxaziridine of the dextrorotatory compound as expected, C-aryl and A-alkyl groups were trans to each other (79MI50800). 

If, however, hydrogen is present in the a-position of the iV-alkyl substituent, 2-alkyl-oxaziridines are easily decomposed by alkali. Base attack on this H atom effects 1,2-elimination at the C—N bond. From (86) and aldimine (87) forms, and a mixture of ammonia and two carbonyl compounds is finally obtained, one of them containing the carbon atom of the original oxaziridine ring, the other originating from the IV-alkyl group (57JA5739). 

Oxidation of A-alkyl imines with dimethyldioxirane (DMD) in a solution of dichloromethane-acetone gives nitrones without the apparent formation of oxaziridines (13). Under the conditions of phase transfer, imines can be oxidized into nitrones upon treatment with permanganate ion MnC>4 (19). 

For oxaziridines the A-inversion barrier is considerably higher than that for similar aziridines. A-Alkyl-3,3-dialkyloxaziridines are resolvable and absolute configurations have been determined (CHEC 5.08.2.3.1). 

Sulfoxides and sulfones can be prepared on cross-linked polystyrene by oxidation of thioethers. The most commonly used reagent for this purpose is MCPBA in DCM [8,12,32,57,80-82] or dioxane [50,83] (Table 8.6), but other oxidants such as H2O2 in acetic acid [34], oxone (Entry 7, Table 8.6), or oxaziridines [84] have also been used. PEG-bound thioethers have been converted into sulfones by oxidation with MCPBA in DCM [52,54] or with Os04/NMO [85], The oxidation of thioethers to sulfoxides requires careful control of the reaction conditions to prevent the formation of sulfones. Sulfones have also been prepared by S-alkylation of polystyrene-bound sulfi-nates (Entries 8 and 9, Table 8.6), by a-alkylation of sulfones (BuLi, THF, alkyl halide [86]), and by addition of sulfinyl radicals to resin-bound alkenes or alkynes (Entry 11, Table 8.6). 

As discussed previously, treatment of thiolates generated from thiols and MeLi with sterically hindered A -sulfonyl-oxaziridine 116 gave the corresponding sulfenate intermediates which were alkylated to afford sulfoxides 118 (Equation 4) <1997JOC8626, 1999PS(153)381, 2004JOC6916>. Oxidation of thiolates generated from aryl thiols... 

An efficient, high-yield synthesis of A-alkyl and A-aryl oxaziridine by oxidation of aldimines with buffered Oxone (potassium peroxymonosulfate) has been introduced by Hajipour and Pyne (Equation (47)) <92JCR(S)388>. Oxidation of the aldimine is accomplished in aqueous NaHC03/ acetonitrile or acetone affording the oxaziridine within 15-30 minutes in excellent yield (95-98%). The active oxidizing species in acetone and acetonitrile are thought to be dimethyldioxirane and peroxyimidic acid [MeC(OOH)=NH), respectively. 

A -Substituted oxaziridines also react with alkyl- and aryl isocyanates at elevated temperatures to give the l,2,4-oxadiazolidin-5-ones 392" °. 

In the oxaziridines (1) ring positions 1, 2 and 3 are attributed to oxygen, nitrogen and carbon respectively. The latter almost always is in the oxidation state of a carbonyl compound and only in rare cases that of a carboxylic acid. Oxaziridinones are not known. The nitrogen can be substituted by aryl, alkyl, H or acyl the substituent causes large differences in chemical behavior. Fused derivatives (4), accessible from cyclic starting materials (Section 5.08.4.1), do not differ from monocyclic oxaziridines. 

Oxaziridines are powerful oxidizing agents. Free halogen is formed from hydrobromic acid (B-67MI50800). Reduction by iodide in acidic media generally yields a carbonyl compound, an amine and two equivalents of iodine from an oxaziridine (1). With 2-alkyl-, 2-acyl and with N-unsubstituted oxaziridines the reaction proceeds practically quantitatively and has been used in characterization. Owing to fast competing reactions, iodide reduction of 2-aryloxaziridines does not proceed quantitatively but may serve as a hint to their presence. 

Oxaziridines substituted in the 2-position with primary or secondary alkyl groups undergo decomposition at room temperature. In the course of some weeks, slow decomposition of undiluted compounds occurs, the pattern of which is analogous to that of acidic or alkaline N—O cleavage (Sections 5.08.3.1.3 and 4), Radical attack on a C—H bond in (109) effects N—O cleavage, probably synchronously (57JA5739). In the example presented here, methyl isobutyl ketone and ammonia were isolated after two hour s heating at 150 °C. 

When )3-scission can occur in the radical, further reactions compete with acid amide formation. Thus oxaziridine (112) with iron(II) ion and acid yields stabilization products of the isopropyl radical. If a-hydrogen is present in the Af-alkyl group, radical attack on this position in (113) occurs additionally according to the pattern of liquid phase decomposition. 

Two substituents on two N atoms increase the number of diaziridine structures as compared with oxaziridines, while some limitations as to the nature of substituents on N and C decrease it. Favored starting materials are formaldehyde, aliphatic aldehydes and ketones, together with ammonia and simple aliphatic amines. Aromatic amines do not react. Suitable aminating agents are chloramine, N-chloroalkylamines, hydroxylamine-O-sulfonic acid and their simple alkyl derivatives, but also oxaziridines unsubstituted at nitrogen. Combination of a carbonyl compound, an amine and an aminating agent leads to the standard procedures of diaziridine synthesis. 

Photoexcited nitrobenzene may be used for benzylic hydroxylation (at C-9) of 17/3-acetoxy-3-methoxyoestra-l,3,5(10)-triene. The photochemistry of the 17/3-nitro-steroid (217) is markedly solvent dependent, the major products being in ether the 17-desnitro-compound (218), in propan-2-ol the hydroxylamine (219), and in EtOH-NaOEt the hydroxamic acid (220) and the cyclopropane (221). The hydroxamic acid (220) is probably formed through the oxaziridine (Scheme 7). Although there are analogies to this in the photochemistry of nitrones and oximes, the photoreduction of a nitroalkane in propan-2-ol to an alkyl-hydroxylamine appears to have no precedent. Further studies of photochemistry of conjugated... 

A typical example is alkylation of the steroid ester 11. Treatment of 1 with LDA in tetrahydrofuran at —78 °C for 1 hour followed by addition of 4-bromo-2-methyl-2-butene in the presence of HMPA at —78 °C to —20 °C furnished an 87 13 mixture of the monoalkylated esters 3a and 3b. The potassium enolate 2 (KHMDS, THF, —78 °C, 1 h) has been hydroxylated with an oxaziridine reagent in 70% yield to give a 3 1 mixture of a-hydroxy derivatives. 

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