Indolizidines reactions

An intramolecular version offers useful synthetic methods for heterocycles. The total syntheses of a- and 7-lycoranes (373 and 374) have been carried out by applying the intramolecular aminochlorination of the carbamate of 5-(2-aminoethyl)-l,3-cyclohexadiene (372) as a key reaction[312,313]. Interestingly, the 4,6- and 5,7-diene amides 375 and 377 undergo the intramolecular amina-tion twice via x-allylpalladium to form alkaloid skeletons ofpyrrolizidine (376) and indolizidine (378), showing that amide group is reactive[314]. 

Loffler-Freitag reaction, 4, 471 Indolizidine, 3-butyl-5-methyl-occurrence, 4, 477... 

Dieckmann reaction, 4, 471 Indolizidine alkaloids mass spectra, 4, 444 Indolizidine immonium salts reactions, 4, 462 Indolizi dines basicity, 4, 461 circular dichroism, 4, 450 dipole moments, 4, 450 IR spectra, 4, 449 reactivity, 4, 461 reviews, 4, 444 stereochemistry, 4, 444 synthesis, 4, 471-476 Indolizine, 1-acetoxy-synthesis, 4, 466 Indolizine, 8-acetoxy-hydrolysis, 4, 452 synthesis, 4, 466 Indolizine, I-acetyl-2-methyI-iodination, 4, 457 Indolizine, 3-acyloxy-cyclazine synthesis from, 4, 460 Indolizine, alkyl-UV spectra, 4, 449 Indolizine, amino-instability, 4, 455 synthesis, 4, 121 tautomerism, 4, 200, 452 Indolizine, 1-amino-tautomerism, 4, 38 Indolizine, 3-amino-synthesis, 4, 461, 470... 

As with i -substituted allyl alcohols, 2,i -substituted allyl alcohols are epoxidized in excellent enantioselectivity. Examples of AE reactions of this class of substrate are shown below. Epoxide 23 was utilized to prepare chiral allene oxides, which were ring opened with TBAF to provide chiral a-fluoroketones. Epoxide 24 was used to prepare 5,8-disubstituted indolizidines and epoxide 25 was utilized in the formal synthesis of macrosphelide A. Epoxide 26 represents an AE reaction on the very electron deficient 2-cyanoallylic alcohols and epoxide 27 was an intermediate in the total synthesis of (+)-varantmycin. 

The intramolecular cycloaddition reaction of enamides has been exploited in alkaloid synthesis (81JOC3763). One successful application is provided by the total synthesis of the fused indolizidine 5 from 4 as a 1 1 mixture of epimers in 43% total yield 5 is a key intermediate in aspidosperma alkaloid synthesis (79JA3294). 

Tetrahydropyridines 103 undergo a Michael reaction to afford [ran.s-(2,3)-cis-(2,6)-trisubstituted piperidines 104 (97T9553). The reaction is stereoselective (a single stereoisomer was obtained) and provides a convenient route to the 5,8-disubstituted indolizidine 105 and 1,4-disubstituted quinolizidine system 106 (found in Dendrobates alkaloids) by introduction of various alkyl, alkenyl, or... 

The aza-[2,3]-Wittig rearrangement of a vinylaziridine-derived quaternary azir-idinium ylide (i.e., [2,3]-Stevens rearrangement) has recently been reported (Scheme 2.53) [86], The aziridinium ylide 219, generated by the intramolecular reaction of a copper carbenoid tethered to a vinylaziridine, underwent a [2,3]-Ste-vens rearrangement to furnish the bicydic amine 220 with the indolizidine skeleton. 

A review article is an intensive survey of a rather narrow field for example, the titles of some recent reviews are Desulfonation Reactions Recent Developments , Pyrrolizidine and Indolizidine Syntheses Involving 1,3-Dipolar Cycloaddtion , and From Corrin Chemistry to Asymmetry Catalysis—A Personal Account. A good review article is of enormous value, because it is a thorough survey of all the work done in the field under discussion. Review articles are printed in review journals and in certain books. The most important review journals in organic chemistry (though most are not exclusively devoted to organic chemistry) are shown in Table A.3. Some of the journals listed in Table A.l, for example, the Bull Soc. Chim. Fr. and J. Organomet. Chem. also publish occasional review articles. 

The utility of lOOC reactions in the synthesis of fused rings containing a bridgehead N atom such as pyrrolizidines, indolizidines, and quinolizidines which occur widely in a number of alkaloids has been demonstrated [64]. Substrates 242 a-d, that possess properly positioned aldoxime and alkene functions, were prepared from proline or pipecolinic acid 240 (Eq. 27). Esterification of 240 and introduction of unsaturation on N by AT-alkylation produced 241 which was followed by conversion of the carbethoxy function to an aldoxime 242. lOOC reaction of 242 led to stereoselective formation of various tricyclic systems 243. This versatile method thus allows attachment of various unsaturated side chains that can serve for generation of functionalized five- or six-membered (possibly even larger) rings. 

The product of the reaction in Entry 8 was used in the synthesis of the alkaloid pseudotropine. The proper stereochemical orientation of the hydroxy group is determined by the structure of the oxazoline ring formed in the cycloaddition. Entry 9 portrays the early stages of synthesis of the biologically important molecule biotin. The reaction in Entry 10 was used to establish the carbocyclic skeleton and stereochemistry of a group of toxic indolizidine alkaloids found in dart poisons from frogs. Entry 11 involves generation of a nitrile oxide. Three other stereoisomers are possible. The observed isomer corresponds to approach from the less hindered convex face of the molecule. 

Reaction of the aldehyde 2-721 and the amine 2-722 gave an imine which, on treatment with Bu3SnH, led to the radical 2-273. This underwent a twofold cycliza-tion to give 2-724. In a similar way, 2-725 and 2-722 gave 2-726 whereas reaction of 2-728 with the selenoamine 2-727 afforded the indolizidine 2-729. Although the yields are low, the transformations are simple and do not depend on complex starting materials. 

Another Rhn-catalyzed decomposition of a a-diazoester as described by Sabe and coworkers [198] was used for the synthesis of indolizidine alkaloids (Scheme 6/2.8). It can be assumed that, first, an ammonium ylide is formed which then undergoes a 1,2-shift with ring-expansion. Thus, reaction of 6/2-40 with Rh2(OAc)4 led to a 72 28 mixture of 6/2-41 and 6/2-42 in 85 % yield. Cu(acac)2 can also be used with even better yields, but lower selectivity (65 35). 

An intramolecular palladium-catalyzed tandem cyclization of dienamides 67 in which the amide nucleophile adds twice has been developed (equation 29)60. This reaction constitutes a formal [4+1] cycloaddition and provides a new route to pyrrolizidine and indolizidine alkaloids. Reaction of dienamides 67 in the presence of catalytic amounts of Pd(OAc)2 and CUCI2/O2 as the oxidant afforded bicyclic compounds 68 in good yields. The pyrrolizidine derivative 68 (R = Me, n = 1) was transformed to the alkaloid ( )-heliotridane. 

Intramolecular 1,3-dipolar cycloaddition reactions of N -(3-alkenyl)nitrones, as presented in Scheme 2.21 le, led to the synthesis of polyhydroxy derivatives of quinolizidine (474) and indolizidine (475) (Scheme 2.234) (732). 

A 1,3-dipolar cycloaddition of the nonstabilized azomethine ylide 6 is the key step in a three-component reaction. The azomethine ylides were generated from (2-azaallyl)stannanes or (2-azaallyl)silanes 5 through an intramolecular iV-alkylation/demetallation cascade. The ylides underwent cycloaddition reactions with dipolarophiles yielding indolizidine derivatives 7-9 <2004JOC1919> (Scheme 1). 

An azomethyne ylide is also invoked as an intermediate in the three-component reaction between the dihydro-isoquinoline 10, an alkylating reagent 11, and the dipolarophile 12, which, in a one-pot process, afforded the indolizidine derivatives 13 <2005S2039> (Scheme 2). 

Finally, intramolecular Diels-Alder reactions, catalyzed by Lewis acids <1999TL7215> or thermally induced <1997JOC2093>, were used to obtain cyano-substituted indolizidine derivatives (Scheme 6). 

Alkyl azides have been involved in the synthesis of indolizidinone derivatives in several ways. One example (Scheme 7) is the intramolecular Schmidt reaction between alkyl azides and ketones which can be used to transform azidoketone 24 into the corresponding indolizidinones 26 through intermediate 25 <2001JOC886> or with epoxides to obtain the indolizidine 27 <2004JOC3093>. 

Reactions where the reduction of a functionalized nitrogen, or the deprotection of an amine group, start a domino process with the sequential formation of the two rings of the indolizidine system, find many examples in the literature. A recent one is provided by the synthesis of (—)-indolizidine 223AB <20040L1493> (Scheme 10). 

An efficient sequential reaction process was developed from y-amino chlorides 42 with propargylate 41 (Scheme 16). In the proposed mechanism, after the alkylation of the nitrogen atom, a subsequent cyclization by the same nucleophilic center induced the formation of intermediate 43, which cyclized to afford the indolizidine 44 <20010L3927, 20050L705>. This synthetic approach found application in the synthesis of indolizidine 223A. 

The extension of the Kulinkovich reaction to succinimide 75 gave a new entry into substituted indolizidines. Initially, it was demonstrated that reacting 75 under the Kulinkovich conditions, with terminal alkenes and... 

Indolizidine alkaloids. The key step in a new stereocontrolled synthesis of these alkaloids, such as castanospermine (5), depends upon the diastereoselective reaction of an azagluco aldehyde with allylmetal reagents catalyzed by Lewis acids (12, 21-22). Thus reaction of allyltrimethylsilane with the aldehyde 1 and TiCL, (excess) in CH2C12 at - 85° results in the product 2, formed by selective chelation of the ot-amino aldehydo group with TiCl4. The product can be converted into 5... 

Pyridinium salts tethered to ketones also undergo cathodic cyclization [1]. The reaction provides a convenient diastereoselective route to quinolizidine and indolizidine derivatives such as 203, 204 and 206, 208, and 209, and appears to hold significant promise as a route to alkaloids. Examples are portrayed and the optimal conditions are listed below the equations. A mercury cathode is preferred, as passivation occurs when lead is used, and the reaction does not occur... 

The construction of an indolizidine skeleton has been successfully obtained by radical cyclizations mediated by (TMS)3SiH. Reaction (7.44) represented a key step in the total synthesis of (—)-slaframine. The two pairs of diastereomers were first separated and then hydrolysed to the corresponding alcohols in a 76% overall yield [55]. On the other hand the cyclization of the A-iodopropyl pyridinones in Reaction (7.45) occurs smoothly at room temperature using Et3B/02 as initiator, to give the desired products with a trifluoromethyl group at the bridgehead position in a syn/anti ratio of 7 3 [56]. 

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