Pyrrolidines rearrangement

The converse situation in which ring closure is initiated by the attack of a carbon-based radical on the heteroatom has been employed only infrequently (Scheme 18c) (66JA4096). The example in Scheme 18d begins with an intramolecular carbene attack on sulfur followed by rearrangement (75BCJ1490). The formation of pyrrolidines by intramolecular attack of an amino radical on a carbon-carbon double bond is exemplified in Scheme 19. In the third example, where cyclization is catalyzed by a metal ion (Ti, Cu, Fe, Co " ), the stereospecificity of the reaction depends upon the choice of metal ion. 

The reaction of methyl propiolate (82) with acyclic enamines produces acyclic dienamines (100), as was the case with dimethyl acetylenedicarboxylate, and the treatment of the pyrrolidine enamines of cycloheptanone, cyclooctanone, cycloundecanone, and cyclododecanone with methyl propiolate results in ring enlargement products (100,101). When the enamines of cyclohexanone are allowed to react with methyl propiolate, rather anomalous products are formed (100). The pyrrolidine enamine of cyclopentanone forms stable 1,2-cycloaddition adduct 83 with methyl propiolate (82). Adduct 83 rearranges to the simple alkylation product 84 upon standing at room temperature, and heating 83 to about 90° causes ring expansion to 85 (97,100). 

Not surprising, the most prevalent synthetic utility is the assembly of the pyrrolidine ring. N-Chloroamine 27 was obtained by treatment of N-methyl-2-cyclopentylethylamine (26) with N-chlorosuccinimide. Under classic Hofmann-Loffler-Freytag reaction conditions, 27 was rearranged either thermally or by UV irradiation in sulfuric acid to bicyclic amine... 

Pyrrolidin-l-yl)-7-trityl-2-azabicyclo[4.1.0]hepta-2,4-dieniumtetrafluoroborates, e.g. 34, on basification with potassium carbonate in acetone, rearrange spontaneously to 7-(pyrrolidin-l-yl)-3-trityl-3//-a/epines, e. g. 35.64... 

In warm acetonitrile 7-piperidino-3-trityl-3i/-azepine (22) rearranges in high yield to the isomeric 3//-azepine 23.64 The corresponding 2-(pyrrolidin-l-yl) and 2-morpholino derivatives behave similarly. Presumably, the gain of amidine resonance energy in tautomer 23 is the driving force behind this rearrangement. 

Analogous rearrangement occurs under much milder conditions when the reactant is a zwitterion generated by deprotonation of an acylammonium ion. Substituted pyrrolidines were used as the chiral auxiliary, with the highest enantioselectivity being achieved with a 2-TBDMS derivative.267... 

As expected, some sequences also occur where a domino anionic/pericyclic process is followed by another bond-forming reaction. An example of this is an anionic/per-icyclic/anionic sequence such as the domino iminium ion formation/aza-Cope/ imino aldol (Mannich) process, which has often been used in organic synthesis, especially to construct the pyrrolidine framework. The group of Brummond [450] has recently used this approach to synthesize the core structure 2-885 of the immunosuppressant FR 901483 (2-886) [451] (Scheme 2.197). The process is most likely initiated by the acid-catalyzed formation of the iminium ion 2-882. There follows an aza-Cope rearrangement to produce 2-883, which cyclizes under formation of the aldehyde 2-884. As this compound is rather unstable, it was transformed into the stable acetal 2-885. The proposed intermediate 2-880 is quite unusual as it does not obey Bredf s rule. Recently, this approach was used successfully for a formal total synthesis of FR 901483 2-886 [452]. 

P-Lactams have been used as a synthon for the preparation of a vast array of compounds. It has been reported that the reduction of 4-(haloalkyl)azetidin-2-ones with LiAlhL is a powerful method for the synthesis of stereodefined aziridines and azetidines <06OL1101>. However, reduction of 4-(haloalkyl)azetidin-2-ones with chloroalane afforded 2-(haloalkyl)azetidines, which were rearranged to 3,4-cw-disubstituted pyrrolidines and piperidines 32 <060L1105>. During these rearrangements, bicyclic azetidinium intermediates were formed which were ring opened by halides. The synthesis of a peptide-... 

The heteroatom version of the vinylcyclopropane rearrangement serves to facilitate alkaloid construction. Scheme 13 outlines a strategy for the pyrrolizidine alkaloid isoretronecanol 211 90). Use of a carboxaldehyde (i.e. 213) as a synthon for the primary alcohol provides an ability to adjust stereochemistry. It also sets up formation of the pyrrolidine ring bearing the aldehyde by an aldol-type condensation of an enol of the aldehyde onto an imine derived from 214. Because of the lability of such systems, introduction of X=PhS imparts stability. The resultant azacyclopentene translates to an imine 215 using the iminocyclopropane rearrangement methodology. Simple condensation of the primary amine 216 with aldehyde 37a then initiates this... 

The Hofmann-Loeffler photolytic rearrangement of chloroamines has been used in early syntheses of ant pyrrolidines (Scheme 26) (129, 164). This reaction, however, suffers from lack of stereo- and regioselectivity. 

Pyrrolines and pyrroles can be readily prepared from the rearrangement of a-aminoallenes. Optically enriched a-aminoallene 137 is rearranged to pyrroline 138 by catalytic silver nitrate (Eq. 13.45) [53], The yield of the reaction is high and the cyclization occurs with high levels of asymmetry transfer. Annulated 3-pyrroline 140 is the product of rearrangement of allenyl pyrrolidine 139 (Eq. 13.46) [53]. 

Surprisingly, the rearrangement of the 4-f-butyldimethylsilyloxy-2-vinyl-pyrrolidines 154 (R =OTBS, R R =H) took another course. The stereochemical outcome had to be rationalized by the passing of a boat-like transition state 156 (bj8) to give the 3,8-trans lactams 157 (Ri=OTBS, entries 15-19, Table 8). The corresponding cis product 158 (Ri=OTBS) resulting from the expected chairlike intermediate 156 (c ) had only once been isolated as a minor compound... 

Claisen rearrangement presumably was the boat-like form 156 (bj0) with minimized 1,3 repulsive interactions resulting in the lactams 157. However, the 2,4-as disubstituted pyrrolidine 159 (R =OTBS, R, R =H) gave the expected lactam diastereomer 158 via a chair-like transition state conformation 160 (entry 16, Table 8) (Scheme 31). 

Both target compounds discussed in this review, kelsoene (1) and preussin (2), provide a fascinating playground for synthetic organic chemists. The construction of the cyclobutane in kelsoene limits the number of methods and invites the application of photochemical reactions as key steps. Indeed, three out of five completed syntheses are based on an intermolecular enone [2+2]-photocycloaddition and one—our own—is based on an intramolecular Cu-catalyzed [2+2]-photocycloaddition. A unique approach is based on a homo-Favorskii rearrangement as the key step. Contrary to that, the pyrrolidine core of preussin offers a plentitude of synthetic alternatives which is reflected by the large number of syntheses completed to date. The photochemical pathway to preussin has remained unique as it is the only route which does not retrosynthetically disconnect the five-membered heterocycle. The photochemical key step is employed for a stereo- and regioselective carbo-hydroxylation of a dihydropyrrole precursor. 

The triflate of (39) has been converted into the pyrrolidine (4 directly by treatment with ammonia. The 6-configuration, inappropriate for a synthesis of anisomycin, was expected, assuming that displacement of the triflate group is the first stage in the reaction. We have so far been unable to rearrange the 6-isomer (45) into the required a-series. This work is being continued. 

An effective method of hexahydrothieno[3,2-c]- and [2,3-c]azocines 146 and 148 syntheses involving a Sommelet-Hauser rearrangement of l,l-dimethyl-2-(2- or 3-thienyl)pyrrolidine salts 145 and 147 under the action of NaNH2 in liquid ammonia has been described (87SC935 Scheme 40). 

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