3-Pyrrolines, oxidation

Diearboxylic acid imi-des. N-Methylpyrrole Lactams. N-Methyl-3-pyrroline Oxidative ring opening. N-Methy lindoline... 

The same rearrangement was observed somewhat later by the irradiation of 5,5-dimethyl-A -pyrroline oxide (13)/ The product (11% yield) was shown to be identical with the oxazirane (14) synthesized from 5,5-dimethyl-A -pyrroline and hydrogen peroxide. 

Condensation of addehydes with N-acyl-V -alkylhydrazines affords an incipient azomethineimine capable of cycloaddition to suitable double bonds. The value of the synthesis is indicated by reactions in Scheme 16. Reaction with benzaldehyde shows a marked regioselectivity. Other interesting dipolar additions are shown in Scheme 17. The interm iacy of a diazacyclopenta-dienone in the decomposition of (59) is clearly shown by the trapping experiments. Also reported are adducts of tetracyanoethylene with 3,6-dialkyl-azepines and the Cope rearrangement of the pyrroline oxide (60) to give... 

Ornithine-Derived Alkaloids. Ornithine (23) undergoes biological decarboxylation reductively to generate either putrescine [110-60-1] (36), or its biological equivalent, and subsequent oxidation and cyclization gives rise to the pyrroline [6724-81-2], (37), C H N. 

Pyrrole oxidizes in air to red or black pigments of uncertain composition. More usehil is the preparation of 2-oxo-A -pyrrolines, which is best carried out by oxidation of the appropriate pyrrole with in pyridine (37), eg, 3,5-dimethyl-ethyl-3-pyrrolin-2-one [4030-24-4] from... 

Catalysts. Silver and silver compounds are widely used in research and industry as catalysts for oxidation, reduction, and polymerization reactions. Silver nitrate has been reported as a catalyst for the preparation of propylene oxide (qv) from propylene (qv) (58), and silver acetate has been reported as being a suitable catalyst for the production of ethylene oxide (qv) from ethylene (qv) (59). The solubiUty of silver perchlorate in organic solvents makes it a possible catalyst for polymerization reactions, such as the production of butyl acrylate polymers in dimethylformamide (60) or the polymerization of methacrylamide (61). Similarly, the solubiUty of silver tetrafiuoroborate in organic solvents has enhanced its use in the synthesis of 3-pyrrolines by the cyclization of aHenic amines (62). 

Pyrrolin-3-ones alkylation, 4, 301 oxidative dimerization, 4, 304 synthesis, 4, 365... 

Pyrroline-N-oxides (12) are sometimes isolated when using zinc-ammonium chloride (19,20), iron-sulfuric acid (14) or hydrazine-Raney nickel (21) as reducing agents. During the reduction, dimerization has been often observed (22). 

A -Pyrroline has been prepared in low yield by oxidation of proline with sodium hypochlorite (71), persulfate (102), and periodate (103). A -Pyrroline and A -piperideine are products of enzymic oxidation via deamination of putrescine and cadaverine or ornithine and lysine, respectively (104,105). This process plays an important part in metabolism and in the biosynthesis of various heterocyclic compounds, especially of alkaloids. 

A -Piperideine-N-oxide was obtained along with a dimeric product by oxidation of N-hydroxypiperidines with mercuric acetate or potassium ferricyanide (107-109). 2l -Pyrroline-N-oxide is formed by oxidation of N-ethylpyrrolidine with hydrogen peroxide with simultaneous formation of ethylene (110). 

The 1,2-, 1,2,5-, 1,3,4-, and 1,2,5-substituted pyrrolidines afford the corresponding pyrrolines very readily by oxidation with mercuric acetate. In the case of 1,2,2-trimethylpyrrolidine (35), the formation of a double bond... 

By means of perbenzoic acid oxidation, a bicyclic oxazirane (233,234) (152) is formed from 5,5-dimethyl-4-phenyl-/l -pyrroline (151). 

A -Pyrroline-N-oxides when unsubstituted in the 2 position readily add hydrogen cyanide. The 1 -hydroxy-2-cyanopyrrolidines thus formed undergo oxidation to 2-cyano-J -pyrroline-N-oxides. 

The dimer of 1-methyl- -pyrroline (39) was obtained by reduction of N-methylpyrrole with zinc and hydrochloric acid (132) and, together with the trimer, by mercuric acetate dehydrogenation of N-methylpyrrolidine (131). J -Pyrroline-N-oxides form dimers in a similar manner (302). Treatment of 1,2-dimethyl-zl -piperideine with formaldehyde, producing l-methyl-3-acetylpiperidine (603), serves as an example of a mixed aldol reaction (Scheme 18). 

In alieyclic systems, more emphasis has been placed on oxidation of nitrones. At least one aldonitrone of the pyrroline series (62) undergoes autoxidation to the hydroxamic acid (63). This is probably a... 

In related work, the reactions of hydrogen peroxide with iron(II) complexes, including Feu(edta), were examined.3 Some experiments were carried out with added 5.5"-dimethyl-1-pyrroline-N-oxide (DMPO) as a trapping reagent fa so-called spin trap) for HO. These experiments were done to learn whether HO was truly as free as it is when generated photochemically. The hydroxyl radical adduct was indeed detected. but for some (not all) iron complexes evidence was obtained for an additional oxidizing intermediate, presumably an oxo-iron complex. 

In addition to a-additions to isocyanides, copper oxide-cyclohexyl isocyanide mixtures are catalysts for other reactions including olefin dimerization and oligomerization 121, 125, 126). They also catalyze pyrroline and oxazoline formation from isocyanides with a protonic a-hydrogen (e.g., PhCH2NC or EtOCOCHjNC) and olefins or ketones 130), and the formation of cyclopropanes from olefins and substituted chloromethanes 131). The same catalyst systems also catalyze Michael addition reactions 119a). 

Recendy, PEN, a-4-pyridyl-oxide-N-t-butyl nitrone (POEN) or 5-5,dimethyl-1, pyrroline-N-oxide (DMPO) were evaluated in models of experimental shock (endo-toxic, traumatic and mesenteric artery occlusion in rats). All three nitrones, when given prior to the insult intraperitoneally, were protective. When the nitrone s spin trapping ability was inactivated by exposure to solar light and air, they were no longer efficacious (Novelli, 1992). 

Anionic/oxidative reaction sequences have been developed in addition to the domino anionic/reductive processes. For example, with regard to the synthesis of novel diaryl heterocycles as COX-2 inhibitors [500], including rofecoxib (Vioxx) 2-972 [501] (which has recently been withdrawn from the market) or the pyrrolin-2-one derivative 2-973 [494], Pal and coworkers reported on a so-far unique domino aldol condensation/oxidation sequence (Scheme 2.218) [503]. 

The enantiomerically pure indolizidine (—)-422 has been synthesized starting from L-malic acid diethyl ester 407. The hydroxyl function of L-malic acid diethyl ester 407 has been protected as dihydropyranyl ether 408 with 2/7-dihydropyran and Amberlyst 15 in pentane at room temperature. The diethyl ester 408 was then reduced with lithium aluminium hydride in diethyl ether under reflux and the newly generated hydroxyl functions then protected with mesyl chloride in the presence of triethylamine in dichloromethane at 0°C. This was converted into newly protected pyrroline nitrone 409 in 44% overall yield through a well-established method (Scheme 90). The regio-isomeric 5-pyrroline-iV-oxide 410 formed in 4% overall yield was easily separated by column chromatography <20000L2475>. 

The pyrroline-iV-oxide 411 lost enantiomeric purity in the deprotection step. The THP protecting group could be deprotected under very mild conditions using Amberlyst 15 in methanol. However, the mixture was obtained in low yield accompanied by partial or total racemization as indicated by variation of specific rotation. Racemization also occurred during purification by silica gel chromatography or recrystallization. The lack of configurational stability of the nitrone 411 may be explained with the occurrence of a fast (not detectable by NMR), nitrone-hydroxyenamine tautomerism (Scheme 91). 

FIGU RE 10.1 The structure of DMPO. The diamagnetic compound 5,5-dimethyl-l-pyrroline-iV-oxide reacts with an unstable radical R to form a relatively stable radical adduct. 

Fig. 3. Preferred TS trajectory for the cycloaddition of 5-substituted pyrroline N-oxides to ring-substituted methylenecyclopropanes...

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