Nitrone reactions amides

Diarylnitrone (31) formation from N-substituted, diaromatic imines has been recognized to require the presence of NADPH/O2, and has been proposed to proceed via the intermediacy of an oxaziridine3 possibly arising from reaction of the parent imines with the putative P-450 [FeO]3+ species in analogy to the oxidation of olefins118. Ring cleavage of the oxaziridine then yields nitrone or amide (equation 10). 

There are a number of thermal and photochemical reactions for which oxaziridine intermediates have been proposed but never isolated. These include, among others, the photochemical Beckmann rearrangement of oximes, many photochemical reactions of aromatic A -oxides, and the thermal rearrangement of nitrones to amides. A brief discussion of the first two seems warranted in this review because they have been studied extensively and some strong inferential evidence for oxaziridine intermediates has been obtained. 

In a more recent study on 1,3-dipolar cycloaddition reactions the use of succi-nimide instead of the oxazolidinone auxiliary was introduced (Scheme 6.19) [58]. The succinimide derivatives 24a,b are more reactive towards the 1,3-dipolar cycloaddition reaction with nitrone la and the reaction proceeds in the absence of a catalyst. In the presence of TiCl2-TADDOLate catalyst 23a (5 mol%) the reaction of la with 24a proceeds at -20 to -10 °C, and after conversion of the unstable succinimide adduct into the amide derivative, the corresponding product 25 was obtained in an endojexo ratio of <5 >95. Additionally, the enantioselectivity of the reaction of 72% ee is also an improvement compared to the analogous reaction of the oxazolidinone derivative 19. Similar improvements were obtained in reactions of other related nitrones with 24a and b. 

As previously described, in basic conditions the proUne-derived a-sulfonyl amide 141 generates the imine function, which afterwards undergoes addition by a nucleophile, e.g., a nitronate ion see the diastereoselective synthesis of the diamino nitroalkane derivative 172, which is the precursor of the piperazine-2-carboxyUc acid 173, through a Nef reaction [45]. Similarly, the addition of the Uthium enolate of ethyl acetateto the a-sulfonyl amide 174 gave the diamino ester derivative 175, wich was then converted to (-)-l-aminopyrrolizidine 176 (Scheme 27). 

Nitrones resulting from the condensation of aldehydes and ketones with N-monosubstituted hydroxylamines were used in a four component Ugi reaction in a one-pot synthesis of a-acyloxyamino-amides (260). 

For the first time, the primary nitrone (formaldonitrone) generation and the comparative quantum chemical analysis of its relative stability by comparison with isomers (formaldoxime, nitrosomethane and oxaziridine) has been described (357). Both, experimental and theoretical data clearly show that the formal-donitrones, formed in the course of collision by electronic transfer, can hardly be molecularly isomerized into other [C,H3,N,0] molecules. Methods of quantum chemistry and molecular dynamics have made it possible to study the reactions of nitrone rearrangement into amides through the formation of oxaziridines (358). 

Beckman rearrangement of nitrone (262) into amide (263) occurs in the reaction with lithium cyanide. However, this reaction gives lactam (264) instead of the expected 2-cyanopyrrolidine 1-oxide (265) (Scheme 2.96) (473). 

This reaction is very important for the synthesis of natural products and for the design of diversely substituted ligands. The use of Sml2 in radical additions of nitrones to 0.,j3-unsaturated amides and esters, constitutes a convenient synthesis of various functionalized y-amino acids with high enantiomeric excess (Schemes 2.114 and 2.115) (531-533). 

Nitronate(47a) is not the only oxazete derivative. For example, sterically hindered nitroalkenes (42b-d) can be prepared by nitration and halogenation of readily available allenes (48). Compounds (42b-d) are rather smoothly isomerized into the corresponding four-membered cyclic nitronates (47b-d) by the first-order reaction equation (168). Storage of nitronate (47c) is accompanied by its slow transformation into acid chloride (47e) from which amide (47f) can be easily synthesized. 

The reactions of ammonia or primary amines with five-membered cyclic nitronates containing the EWG -group at the C-5 atom involve deoxygenation of the nitronate fragment, aromatization of the ring, and amidation of the ester... 

Oxaziranes are in a real sense active oxygen compounds and exhibit many reactions grossly analogous to those of organic peroxides. Thus they undergo one electron transfer reaction with ferrous salts and on pyrolysis they are converted to amides. Oxaziranes are also useful synthetic intermediates since in appropriate cases they may be isomerized to aromatic nitrones which are a convenient source of N-alkylhydroxylamines. The reaction of oxaziranes with peracids also provides a source of nitrosoal-kanes and is in many instances the method of choice for preparation of these compounds. ... 

Nadolol, 110 Nafenopin, 214 Nafomine, 212 NafT-onyl, 213 Nalbuphine, 319 Nalidixic acid, 370, 469 Nalmexone, 319 Nalorphine, 318 Naloxone, 318, 323 Naltrexone, 319 Naranol, 454 Nef reaction, 2 Nefopam, 447 Nequinate, 369 Nexeridine, 17 Nicergoline, 478 Niclos amide, 94 Nifedipine, 283 Nifuratrone, 238 Nifurdazil, 239 Nifurimide, 239 Nifui oxime, 238 Nifurpirinol, 240 Nifurcguinazol, 383 Nifursemizone, 238 Nifurthiazole, 241 Nimazone, 260 Nimorazole, 244 Niridazole, 269 Nisobamate, 22 Nithiazole, 268 Nitronic acid, 2 Nivazol, 159 Nocardicins, 435 Noracymethadol, 58... 

The reactions of nitrilium salts with nitrones usually give tars. However, pyridine-A -oxides afford oxazolium salts, which rearrange in solution to more stable amides (Scheme 105) <71TL1947,75JOC4l>. 

The second class of benzo-fused heterocycles accessible from benzofuroxans are benzimidazole oxides. In this case only one carbon from the co-reactant is incorporated in the product. With primary nitroalkanes 2-substituted l-hydroxybenzimidazole-3-oxides (46) are formed via displacement of nitrite, and / -sulfones behave similarly. The nitrile group of a-cyanoacetamides is likewise eliminated to alford 2-amide derivatives (46 R = CONRjX and the corresponding esters are formed in addition to the expected quinoxaline dioxides from acetoacetate esters. Under similar conditions secondary nitroalkyl compounds afford 2,2-disubstituted 2//-benzimidazole-1,3-dioxides (47). Benzimidazoles can also result from reaction of benzofuroxans with phosphorus ylides <86T3631>, nitrones (85H(23)1625>, and diazo compounds <75TL3577>. 

The acyclic precursor is an oc, 3-unsaturated amido aldehyde that was condensed with iV-methylhydroxylamine to generate the nitrone ( )-48, which then underwent a spontaneous cycloaddition with the alkene to afford the 5,5-ring system of the isoxazolidinyl lactam 47. The observed product arises via the ( )-nitrone transition state A [or the (Z)-nitrone equivalent] in which the position of the benzyl group ot to the nitrone effectively controls the two adjacent stereocenters while a third stereocenter is predicted from the alkene geometry. Both transition states maintain the benzyl auxiliary in an equatorial position and thus avoid the unfavorable 1,3-diaxial interaction with the nitrone methyl or oxygen found in transition state B. Semiempirical PM3 calculations confirm the extra stability, predicting exclusive formation of the observed product 47. Related cycloadducts from the intramolecular reaction of nitrones containing ester- rather than amide-tethered alkene functionality are also known (83-85). 

The a,p-unsaturated amides 180-188a have all been used in 1,3-dipolar cycloadditions with nitrile oxides, and some of them represent the most diastereoselective reactions of nitrile oxides. The camphor derivative 180 of Chen and co-workers (294), the sultam 181 of Oppolzer et al. (295), and the two Kemp s acid derived compounds 186 (296) and 187 (297) described by Curran et al. (296) are excellent partners for diastereoselective reactions with nitrile oxides, as very high diastereos-electivities have been observed for all of them. In particular, compound 186 gave, with few exceptions, complete diastereoselection in reactions with a wide range of different nitrile oxides. Good selectivities were also observed when using compounds 183 (298) and 184 (299-301) in nitrile oxide cycloadditions, and they have the advantage that they are more readily available. Curran and co-workers also studied the 1,3-dipolar cycloaddition of 187 with silyl nitronates. However, compared to the reactions of nitrile oxides, lower selectivities of up to 86% de were obtained (302). 

Mukund Sibi of North Dakota State University has developed (J. Am. Chem. Soc. 2004,126,718) a powerful three-component coupling, combining an a,(5-unsaturated amide 9, a hydroxylamine 10, and an aldehyde 11. The hydroxylamine condenses with the aldehyde to give the nitrone, which then adds in a dipolar sense to the unsaturated ester. The reaction proceeds with high diastereocontrol, and the absolute configuration is set by the chiral Cu catalyst. As the amide 9 can be prepared by condensation of a phosphonacetate with another aldehyde, the product 12 can be seen as the product of a four-component coupling, chirally-controlled aldol addition and Mannich condensation on a starting acetamide. 

The synthetic approach used in this work is shown in Scheme 9. Two known solution pathways were used to convert shikimic acid to an epoxide intermediate. In fact, both the (-)35 and the (+)36 enantiomers were formed. After minor synthetic transformations, these epoxides were linked to Ten-tagel S aminomethyl resin with an o-nitrophenyl-derived photocleavable linker 7437 via amide bond formation to give intermediate 75. The first point of variation was added via various iodo-benzyl nitrone carboxylic acids 76 via 1,3-dipolar addition/esterification reactions. Highly constrained resin-bound tetracyclic hydrooxazoles 77 were thereby produced. 

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