Pyrrolines, examples

A/ -Methoxycarbonyl-2-pyrroline undergoes Vilsmeier formylation and Friedel-Crafts acylation in the 3-position (82TL1201). In an attempt to prepare a chloropyrroline by chlorination of 2-pyrrolidone, the product (234) was obtained in 62% yield (8UOC4076). At pH 7, two molecules of 2,3-dihydropyrrole add together to give (235), thus exemplifying the dual characteristics of 2,3-dihydropyrroles as imines and enamines. The ability of pyrrolines to react with nucleophiles is central to their biosynthetic role. For example, addition of acetoacetic acid (possibly as its coenzyme A ester) to pyrroline is a key step in the biosynthesis of the alkaloid hygrine (236). 

When the chain between the azirine ring and the alkene end is extended to three carbon atoms, the normal mode of 1,3-intramolecular dipolar cycloaddition occurs. For example, irradiation of azirine (73) gives A -pyrroline (74) in quantitative yield 77JA1871). In this case the methylene chain is sufficiently long to allow the dipole and alkenic portions to approach each other in parallel planes. 

A number of examples of acid catalyzed ring expansion of acyl and thioacyl azetidines to sbc-membered rings have been reported (B-73MI50903). This type of rearrangement (Scheme 2) is similar to the more general vinylaziridine to pyrroline ring expansion. 

The alkylation of imines by an alkyl halide to give an iminium salt will be illustrated by selected reactions over a period of years. A more complete survey is available (88). Decker and Becker (89) prepared a number of iminium salts (91, for example) by mixing methyl iodide and aromatic imines in benzene. 2,5-Dimethyl-2-pyrroline (92) has been alkylated and the... 

Heterocyclic enamines often undergo two-step 1,3 cycloaddition with methyl vinyl ketone. This involves electrophilic attacks by an olefinic carbon and by a carbonyl carbon (24,25). For example, 1,2-dimethyl-Zl -pyrroline (14), when treated with methyl vinyl ketone, produces 1,6-dimethyl-2,3,4,5-tetrahydroindole (15) (24). The requirement which must be met so that this type of cyclization reaction can take place is that the a position of the heterocyclic enamine be carbon substituted. This provides... 

The piperideine derivatives have not been studied as extensively as the analogous pyrrolines (151,152). The imino structure has been established, for example, for the alkaloid y-coniceine (146) (46). The great influence of conjugation on the structure is seen with l-(a-picolyl)-6,7-methylenedioxy-3,4-dihydroisoquinoline (47), possessing an enamine structure, whereas the analogous 1-methyl derivative (48) possesses an imine structure according to infrared spectra (152,153). 

An explanation of the exclusive N methylation of 1,2-dimethyl-J -piperi-deine by means of methyliodide is more difficult. Pyrrolines and piperideines which are not alkylated on the nitrogen atom afford only quaternary ammonium salts on alkylation (203-205), for example 119. 

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). 

A good example of a concerted cheletropic elimination is the reaction of 3-pyrroline with IV-nitrohydroxylamine, which gives rise the the diazene 21, which then undergoes elimination of nitrogen. 

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]. 

For example, the reaction of nitronates (123) with a zinc copper pair in ethanol followed by treatment of the intermediate with aqueous ammonium chloride a to give an equilibrium mixture of ketoximes (124) and their cyclic esters 125. Heating of this mixture b affords pyocoles (126). Successive treatment of nitronates (123) with boron trifluoride etherate and water c affords 1,4-diketones (127). Catalytic hydrogenation of acyl nitronates (123) over platinum dioxide d or 5% rhodium on aluminum oxide e gives a-hydroxypyrrolidines (128) or pyrrolidines 129, respectively. Finally, smooth dehydration of a-hydroxypyrrolidines (128) into pyrrolines (130f) can be performed. 

Each transformation shown in Scheme 3.104 involves consecutive reactions, for which optimal procedures were found. For example, path b involves four transformations successive reduction of the nitronate fragment to the oximino group and then to the imino group followed by keto imino condensation and dehydration of intermediate pyrroline. 

The optimized protocol has also been applied to a wide range of open-chain and cyclic dienes (for selected examples, see Table 11.11) [113], The latter generally give higher yields than non-terminal alkenes and cycloalkenes, except for strained ones such as JV-benzyl-pyrroline, cyclopentene, and norbornene (Table 11.10, entries 20—22). 

Curiously, the synthesis of shihunine via a phenylcyclopropylimine (187) is the sole example of a simple pyrrolidine alkaloid obtained according to this general pyrroline synthesis (188) (Scheme 40). 

There is some evidence, from EPR spectroscopy and analysis of spin-trapped adducts, to suggest that OH may indeed be formed by activated neutrophils. However, caution must be exercised in interpreting such data because 02"-generated adducts may decay to form adducts that resemble those generated directly from -OH. For example, 5,5-dimethyl-l-pyrroline-l-oxide (DMPO) can react with C>2 to form DMPO-OOH, and with OH to form DMPO-OH formation of the latter adduct in phagocytosing neutrophils is taken as evidence for OH formation. However, two facts must be considered ... 

In this type of spin traps, 5,5-dimethyl-l-pyrroline-Af-oxide (DMPO) deserves particular mention. DMPO is widely employed as a spin trap in the detection of transient radicals or ion-radicals in chemical and biological systems (see, e.g., Siraki et al. 2007). Characteristic ESR spectra arising from the formation of spin adducts are used for identification of specific spin species. In common opinion, such identification is unambiguous. However, in reactions with superoxide ion (Villamena et al. 2004, 2007b), carbon dioxide anion-radical (Villamena et al. 2006), or carbonate anion-radical (Villamena et al. 2007a), this spin trap gives rise to two adducts. Let us consider the case of carbonate anion-radical. The first trapped product arises from direct addition of carbonate anion-radical, second adduct arises from partial decarboxylation of the first one. Scheme 4.25 illustrates such reactions based on the example of carbonate anion-radical. 

The reaction of l-methyl-2-(methylmercapto)-2-pyrroline (282) with DMAD is known to give a dihydroazepine derivative (283) (Eq. (38)1. The recent report of the reaction of 1-methyl-2-pyrrolidone dimethyl-acetal (284) with DMAD to give products like 286, 287, 288, and 289 may be interpreted as essentially the reaction of the enamine system (285) (Scheme 45). Other examples of the reaction of enamines include the reaction of the pyrrolidinopentenone (290) to give the phthalate (293)... 

The cyano-substituted nitrile ylides 123 have been generated via 1,1-elimination reactions. For example, the benzyhdene derivative 122 (R=Ph) eliminated benzene on vapor phase pyrolysis to give 123 (R=Ph), which reacted via 1,5-electrocycli-zation [see also (66)] to give the isoindole 124 (41%) (67). In a similar way, 122 [R=(CH2)3CH=CH2] gave the corresponding nitrile yhde that reacted via intramolecular cycloaddition to give the pyrroline derivative 126. 

Nuclear magnetic resonance (n.m.r.) studies have revealed that 4-amino-4-deoxy-L-xylose,35,350 4-amino-4,5-dideoxy-L-xylose,356 and 4-amino-4-deoxy-D-glucose34 (40) exist as equilibrium mixtures for example, of the pyrrolidine 40, the pyrroline 39 formed by its dehydration, and a dimer (41), the equilibrium lying strongly towards the last. Similar studies have shown that the hydrochlorides of 4-amino-... 

Sorangium cellulosum is an ubiquitous soil bacterium that belongs to the order Myxococcales. It has the ability to glide over solid surfaces, to live in a biofilm and form fruiting bodies. Members of this taxon are a particularly rich source of metabolites with remarkable biological activities [177]. From one strain, another example of N-acyl-4-methoxy-3-pyrrolin-2-ones has been isolated. Eliamid (110) has been claimed to have cytostatic, nematocidal and fungicidal activities [178]. 

This sequence can provide easy access to substituted pyrrolines. For example, the simple synthesis of 2-pheny Ipyrroline ... 

There are two possible types of dihydro-furans and -thiophenes (cf. 214, 215) and examples of both are known. There are three possible classes of dihydropyrroles /V-unsubstituted 2-pyrrolines (216) are in tautomeric equilibrium with the corresponding 1-pyrrolines (217). 

Perhydropyrrolo[l,2-fc]isoxazoles result from 1,3-dipolar cycloaddition of cyclic nitrones with alkenes. The high regio- and stereoselectivity of this cycloaddition has been used to control the stereochemistry in the synthesis of natural products. As one example, pyrroline N-oxide (70) and 3,4-dimethoxystyrene gave a diastereomeric mixture of pyrroloisoxazoles (71) and (72), in nearly quantitative yield with preferential formation of (71). 

The polymeric pyrrolic autoxidation products probably result from the oxidized monomeric systems, which are analogous in structure to those isolated from photooxidation and peroxide oxidation reactions. Thus, for example, analysis of the products of the autoxidation of 1-methylpyrrole (Scheme 47) would suggest that 1 -methyl-A3-pyrrolin-2-one (153) is initially formed from a radical reaction of the pyrrole with triplet oxygen. This reaction sequence should be compared with that proposed for the oxidation of pyrroles with hydrogen peroxide (Scheme 50), which yields (181), (182) and (183) as the major isolable products. The acid-catalyzed reaction of a pyrrole with its oxidation product e.g. 153) also results in the formation of polymeric material and the formation of pyrrole black is probably a combination of oxidation and acid-catalyzed polymerization processes. 

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