Cyclopentene, oxidation oxidative cyclization

The domino carbonylation and Diels-Alder reaction proceed only as an intramolecular version. Attempted carbonylation and intermolecular Diels-Alder reaction of conjugated 2-yne-4-enyl carbonates 101 in the presence of various alkenes as dienophiles give entirely different carbocyclization products without undergoing the intermolecular Diels-Alder reaction. The 5-alkylidene-2-cyclopenten-4-onecarboxy-lates 102 were obtained unexpectedly by the incorporation of two molecules of CO in 82% yield from 101 at 50 °C under 1 atm [25], The use of bidentate ligands such as DPPP or DPPE is important. The following mechanism of the carbocyclization of 103 has been proposed. The formation of palladacyclopentene 105 from 104 (oxidative cyclization) is proposed as an intermediate of 108. Then CO insertion to the palladacycle 105 generates acylpalladium 106. Subsequent reductive elimination affords the cyclopentenone 107, which isomerizes to the cyclopentenone 108 as the final product. 

The carbonylation of cyclopentene oxide with retention of configuration is an exception to this trend. This exception presumably results from conformational constraints during the cyclization step. See reference 216. 

Diacetates of 1,4-butenediol derivatives are useful for double allylation to give cyclic compounds. l,4-Diacetoxy-2-butene (126) reacts with the cyclohexanone enamine 125 to give bicyclo[4.3.1]decenone (127) and vinylbicy-clo[3.2.1]octanone (128)[85,86]. The reaction of the 3-ketoglutarate 130 with cij-cyclopentene-3,5-diacetate (129) affords the furan derivative 131 [87]. The C- and 0-allylations of ambident lithium [(phenylsulfonyl)methylene]nitronate (132) with 129 give isoxazoline-2-oxide 133, which is converted into c -3-hydroxy-4-cyanocyclopentene (134)[S8]. Similarly, chiral m-3-amino-4-hyd-roxycyclopentene was prepared by the cyclization of yV-tosylcarbamate[89]. 

Volume 75 concludes with six procedures for the preparation of valuable building blocks. The first, 6,7-DIHYDROCYCLOPENTA-l,3-DIOXIN-5(4H)-ONE, serves as an effective /3-keto vinyl cation equivalent when subjected to reductive and alkylative 1,3-carbonyl transpositions. 3-CYCLOPENTENE-l-CARBOXYLIC ACID, the second procedure in this series, is prepared via the reaction of dimethyl malonate and cis-l,4-dichloro-2-butene, followed by hydrolysis and decarboxylation. The use of tetrahaloarenes as diaryne equivalents for the potential construction of molecular belts, collars, and strips is demonstrated with the preparation of anti- and syn-l,4,5,8-TETRAHYDROANTHRACENE 1,4 5,8-DIEPOXIDES. Also of potential interest to the organic materials community is 8,8-DICYANOHEPTAFULVENE, prepared by the condensation of cycloheptatrienylium tetrafluoroborate with bromomalononitrile. The preparation of 2-PHENYL-l-PYRROLINE, an important heterocycle for the synthesis of a variety of alkaloids and pyrroloisoquinoline antidepressants, illustrates the utility of the inexpensive N-vinylpyrrolidin-2-one as an effective 3-aminopropyl carbanion equivalent. The final preparation in Volume 75, cis-4a(S), 8a(R)-PERHYDRO-6(2H)-ISOQUINOLINONES, il lustrates the conversion of quinine via oxidative degradation to meroquinene esters that are subsequently cyclized to N-acylated cis-perhydroisoquinolones and as such represent attractive building blocks now readily available in the pool of chiral substrates. 

The last synthesis to evolve which is due to Ito and his coworkers is interesting in that it relies on a stereospecific skeletal rearrangement of a bicyclo[2.2.2]octane system which in turn was prepared by Diels-Alder methodology (Scheme XLVIII) Heating of a toluene solution of cyclopentene 1,2-dicarboxylic anhydride and 4-methylcyclohexa-l,4-dienyl methyl ether in the presence of a catalytic quantity of p-toluenesulfonic acid afforded 589. Demethylation was followed by reduction and cyclization to sulfide 590. Desulfurization set the stage for peracid oxidation and arrival at 591. Chromatography of this intermediate on alumina induced isomerization to keto alcohol 592. Jones oxidation afforded diketone 593 which had earlier been transformed into gymnomitrol. 

The electrochemical reduction of y-oxoesters like 115, synthesized via the cyclopropane route, results in cyclization with participation of the olefinic unitn>. This reaction provides interesting cyclopentanol derivatives, which can be transformed to the corresponding cyclopentenes. Alternatively a fragmentation to medium sized ketones like 116 occurs after saponification and anodic oxidation 77>. 

The core skeleton of geissoschizine, an important biosynthetic precursor to numerous polycyclic indole scaffolds, was the target of a nickel-catalyzed alkylative coupling strategy. Cyclization precursor 13 was prepared by ozonolysis and double reductive amination of cyclopentene 12 (Scheme 8.13) [35]. Nickeldeprotection/oxidation sequence followed, and chromatography led to complete inversion of the C3 stereocenter. A Fisher indole synthesis followed to afford ( )-deformyl-isogeissoschizine, the core skeleton of geissoschizine. 

With hydrogen peroxide or, better, t-butylhydroperoxide as the oxidant, the combination of palladium acetate and hydroquinone forms an efficient catalyst system, which does not require other cocatalysts. Using t-butylhydroperoxide as the oxidant, it is possible to react a series of different carboxylates with alkenes in methylene chloride solution. For instance, (5)-0-acetylmandelic acid was reacted with cyclohexene to give the addition product with a modest chiral induction (de ca. 20%). Also, intramolecular cyclization could be achieved for example, 2-cyclopenten-l-acetic acid gave mainly the allylic lactone in good yield, accompanied by a small amount of the double bond isomer (Scheme 9). 

CycUzation.—4,4-Disubstituted 1,6-dienes (38) undergo cyclization to the substituted cyclopentenes (39) in good yield in the presence of PdCl2 or Pd(OAc)2- The reaction is catalytic, even in the absence of an oxidant like cupric chloride. 

Cookson and Lane have shown that 2-hydroxycyclopentanones (45) (acyloins) are obtained by cyclization of pentanedials with thiazolium salts subsequent oxidation of the acyloins then provides the corresponding 2-hydroxycyclopent-2-enones (46), several members of which are important flavouring materials. The intramolecular reductive coupling of keto-aldehyde (47) with Ti° has provided a convenient route to the cyclopentene (48). ... 

Homologation of the aldehyde 13 and subsequent oxidation were straightforward, but subsequent methylenation of the hindered carbonyl was not. At last, it was found that Peterson olefination worked well. Metathesis then delivered the cyclopentene 2. The last carbons of the skeleton were added by intramolecular aldol cyclization of the thioester 16. 

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