Pyrroline Complexes

In summary, the metal can be readily removed from both 1//-pyrrole and 3-pyrroline (including azanorbomene) complexes to give a wide variety of highly functionalized molecules not readily obtained from the aromatic precursors without the use of osmium. The inherent instability of 2-pyrrolines prevents clean decomplexation unless quatemization or acylation of the nitrogen is carried out prior to oxidation of the metal. 

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Both 2H- and 3f/-pyrrolium isomers are moderately susceptible to nucleophilic addition at the iminium carbon. Their reactivity, however, is greatly reduced by 7t-backbonding effects of the metal to the point that they resist hydrolysis, even in aqueous solution. Dihapto-coordinated 2-and 3-pyrroline complexes can be synthesized in good yields by reduction of 3H- and 2f/-pyrrolium complexes, respectively (Figure 14).12b Hydride reduction of the 3/f-pyrrolium isomers of 1-methylpyrrole (28),... 

Intermolecular addition of carbon nucleophiles to the ri2-pyrrolium complexes has shown limited success because of the decreased reactivity of the iminium moiety coupled with the acidity (pKa 18-20) of the ammine ligands on the osmium, the latter of which prohibits the use of robust nucleophiles. Addition of cyanide ion to the l-methyl-2//-pyr-rolium complex 32 occurs to give the 2-cyano-substituted 3-pyrroline complex 75 as one diastereomer (Figure 15). In contrast, the 1-methyl-3//-pyrrolium species 28, which possesses an acidic C-3-proton in an anti orientation, results in a significant (-30%) amount of deprotonation in addition to the 2-pyrroline complex 78 under the same reaction conditions. Uncharacteristically, 78 is isolated as a 3 2 ratio of isomers, presumably via epimerization at C-2.17 Other potential nucleophiles such as the conjugate base of malononitrile, potassium acetoacetate, and the silyl ketene acetal 2-methoxy-l-methyl-2-(trimethylsiloxy)-l-propene either do not react or result in deprotonation under ambient conditions. 

In addition to the high regiochemistry observed, the bulky osmium pentaammine metal center also effectively blocks one face of the pyrrole ring from attack. This directs each transformation carried out on the complex to occur on the same face of the pyrrole ring. For example, in the synthesis of 3-pyrroline complex 74, both protonation and hydride addition occur from the same face of the pyrrole ring, producing 74 exclusively as the c/s-isomer. This feature is also illustrated in the synthesis of pyrrolizinone 109 vide infra), where a stereoselective hydride reduction allows the preparation of 109 as only one diastereomer. 

Liberation of the organic ligand in 3-pyrroline complexes can be accomplished in good yield either by oxidation (CeIV or DDQ), or by heating under anaerobic conditions.12,14 Synthesis of the pyrrolizinone 109 is accomplished by first reducing the ring-opened 2//-pyrrolium... 

Iron-alkene complexes have also been used for the synthesis of -lactams (Scheme 25). The alkene complex (19) is transfonned into the pyrroline complex (20) on exposure to ammonia. Reduction with NaBH4 gives a mixture of stereoisomeric pyrrolidine complexes which are then converted on heating to the diastereomeric chelate (21). Oxidation with air or silver oxide produces the lactam (22). 

Complex reactions occur on the autoxidation of pyrroles (see Section 3.05.1.4) predictably, susceptibility to autoxidation increases with increasing alkyl substitution, llie photosensitized reaction of pyrrole and oxygen yields 5-hydroxy-A -pyrrolin-2-one, probably by way of an intermediate cyclic peroxide (Scheme 28) (76JA802). 

Partial hydrogenation of pyrrole derivatives and partial dehydrogenation of pyrrolidines afford /I -pyrrolines (80-82). However, because of the complex nature of the reaction, it is of little preparative value. The same is true for isomerization of /) -pyrrolines to /) -pyrrolines (83). A photodehydrogenation of 2,6-dimethylpiperidine (26) has been observed recently, affording 2,6-dimethyl-3,4,5,6-tetrahydropyridine (27) in a good yield (84)-... 

Reduction of l-methyl-2-alkyl-.d -pyrroline and l-methyl-2-alkyl-.d -piperideine perchlorates with complex hydrides prepared in situ by partial decomposition of lithium aluminum hydride with the optically active alcohols (—)-menthol and (—)-borneol affords partially optically active l-methyl-2-alkyl pyrrolidines (153, n = 1) and 1-methy 1-2-alkyl piperideines (153, n = 2), respectively (241,242). 

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. 

The regioselectivity observed in these reactions can be correlated with the resonance structure shown in Fig. 2. The reaction with electron-rich or electron-poor alkynes leads to intermediates which are the expected on the basis of polarity matching. In Fig. 2 is represented the reaction with an ynone leading to a metalacycle intermediate (formal [4C+2S] cycloadduct) which produces the final products after a reductive elimination and subsequent isomerisation. Also, these reactions can proceed under photochemical conditions. Thus, Campos, Rodriguez et al. reported the cycloaddition reactions of iminocarbene complexes and alkynes [57,58], alkenes [57] and heteroatom-containing double bonds to give 2Ff-pyrrole, 1-pyrroline and triazoline derivatives, respectively [59]. 

The reaction of alkenylcarbene complexes and imines in the presence of a Lewis acid generates pyrroline derivatives as a result of a [3C+2S] cyclisation process [76]. This reaction has been extended to an asymmetric version by the use of chiral alkenylcarbene complexes derived from several chiral alcohols. However, the best results are found when (-)-8-phenylmenthol-derived complexes are used and catalytic amounts of Sn(OTf)2 are added to the reaction. In these conditions high levels of trans/cis selectivity are achieved and the hydrolysis of the major tram diastereoisomers allows the preparation of optically pure 2,5-disubstituted-3-pyrrolidinone derivatives (Scheme 29). 

The Rh and Ir complexes 85-88 (Fig. 2.14) have been tested for the intramolecular hydroamination/cyclisation of 4-pentyn-l-amine to 2-methyl-1-pyrroline (n = 1). The reactions were carried out at 60°C (1-1.5 mol%) in THF or CDCI3 The analogous rhodium systems were more active. Furthermore, the activity of 87 is higher than 85 under the same conditions, which was attributed to the hemilabihty of the P donor in the former complex, or to differences in the trans-eSects of the phosphine and NHC ligands, which may increase the lability of the coordinated CO in the pre-catalyst [75,76]. 

In the case of 3-alkynylamines, IH proceeds exclusively in a S-Endo-Dig process to give substituted 1-pyrrolines. The best catalysts are palladium complexes (Eq. 4.69) the reaction fails for terminal alkyne owing to the formation of a stable palladium acetylide [278]. 

A complex product containing three A3-pyrrolines is obtained from the cooligomerization of diphenylbutadiyne with diaryl and dicyclohexyl carbo-... 

Akiyama developed a novel [3+2] cycloaddition reaction of alkenyl Fischer carbene complexes 11 with simple imines 12 in the presence of a catalytic amount of GaCb to produce 3-alkoxy-2,5-disubstituted-3-pyrroline derivatives 13 <00JA11741>. 

Chromium carbene complexes have also been known to react with imine equivalents to afford /3-lactam derivatives234. Furthermore, [3 + 2]-cycloaddition of an alkenylchromium carbene 133 with imines proceeded to afford 3-pyrroline derivatives 134 in the presence of a Lewis acid catalyst (Equation (21)),235 where GaClj or Sn(OTf)2 were efficient promoters. Alkenylcarbenes bearing chiral auxiliaries afforded the desired cycloadduct in optically pure form. 

Cyclohydrocarbonylation of unsymmetrical amidodiene 29 catalyzed by Rh-BIPHEPHOS complex yielded dehydropiperidine aldehyde 31 as the sole product (Scheme S). The fact that no pyrroline was formed indicates that this reaction was extremely chemo- and regioselective so that the hydroformylation took place at the homoallylic olefin moiety exclusively, yielding the linear aldehyde intermediate 30. 

The palladium catalysed substitution reaction of allylic systems has also been utilised in the formation of five membered rings. Intramolecular nucleophilic attack of the amide nitrogen atom on the allylpalladium complex formed in the oxidative addition of the allyl acetate moiety on the catalyst led to the formation of the five membered ring (3.63.). In the presence of a copper(II) salt the intermediate pyrroline derivative oxidized to pyrrole.80... 

Alike olefins, allenes also undergo palladium mediated addition in the presence of N-H or O-H bonds. Although these reactions show some similarity to Wacker-type processes, from the mechanistic point of view they are quite different. Allenes, such as the cr-aminoallene in 3.69., usually undergo addition with palladium complexes (e.g. carbopalladation in 3.69. and 3.70., or hydropalladation in 3.71.), which leads to the formation of a functionalized allylpalladium complex. Subsequent intramolecular nucleophilic attack by the amino group leads to the closure of the pyrroline ring.87... 

Scheme 81 shows a highly enantioselective C—C bond formation in the BINAP-Pd(II) diacetate-catalyzed reaction of aryl triflate and 2,3-dihydiofuran (193). A BINAP-Pd(0) species generated by the action of a tertiary amine on the Pd(II) complex is the actual catalyst. Enhancement of the enantioselectivity through kinetic resolution of the intermediate is indicated by the double-bond isomer having opposite absolute configuration at the arylated carbon. / -Substituted 2-pyrrolines may also be used as olefinic substrates. 

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