Acetic 1-cyclohexenyl

The wM-diacetate 363 can be transformed into either enantiomer of the 4-substituted 2-cyclohexen-l-ol 364 via the enzymatic hydrolysis. By changing the relative reactivity of the allylic leaving groups (acetate and the more reactive carbonate), either enantiomer of 4-substituted cyclohexenyl acetate is accessible by choice. Then the enantioselective synthesis of (7 )- and (S)-5-substituted 1,3-cyclohexadienes 365 and 367 can be achieved. The Pd(II)-cat-alyzed acetoxylactonization of the diene acids affords the lactones 366 and 368 of different stereochemistry[310]. The tropane alkaloid skeletons 370 and 371 have been constructed based on this chemoselective Pd-catalyzed reactions of 6-benzyloxy-l,3-cycloheptadiene (369)[311]. 

This interpretation is supported by results on the acetolysis of the bicyclic tosylates 9 and 10. With 9, after three months in acetic acid at 150°C, 90% of the starting material was recovered. This means that both ionization to a cyclopropyl cation and a concerted ring opening must be extremely slow. The preferred disrotatory ring-opening process would lead to an impossibly strained structure, the /ran -cyclohexenyl cation. In contrast, the stereoisomer 10 reacts at least 2x10 more rapidly because it can proceed to a stable cis-cyclohexenyl cation ... 

Electrochemical fluorination of a-cyclohexenyl-substituted carboxylic (acetic, propanoic, butanoic, and pentanoic) acid esters (methyl, ethyl, and propyl) results in a series of both perfluoro-9-alkyl-7-oxabicyclo[4 3 OJnonanes and per-fluoro-8-alkoxy-9-alkyl-7-oxabicyclo[4.3.0]nonanes [<8S] (equation 19)... 

Ethyl 1-bromocyclohexanecarboxylate, when treated with magnesium in anhydrous ether-benzene with subsequent addition of cyclohexanone, yields ethyl l-(l-hydroxycyclohexyl)cyclo-hexanecarboxylate. Dehydration and saponification give rise to l-(l-cyclohexenyl)cyclohexanecarboxylic acid, which upon decarboxylation at 195° yields cyclohexylidenecyclohexane in 8% overall yield, m.p. 540.4 This olefin has also been prepared by the debromination of 1,1 -dibromobicyclohexyl with zinc in acetic acid. ... 

Potassium or lithium derivatives of ethyl acetate, dimethyl acetamide, acetonitrile, acetophenone, pinacolone and (trimethylsilyl)acetylene are known to undergo conjugate addition to 3-(t-butyldimethylsiloxy)-1 -cyclohexenyl t-butyl sulfone 328. The resulting a-sulfonyl carbanions 329 can be trapped stereospecifically by electrophiles such as water and methyl iodide417. When the nucleophile was an sp3-hybridized primary anion (Nu = CH2Y), the resulting product was mainly 330, while in the reaction with (trimethylsilyl)acetylide anion the main product was 331. 

Solvolyses of these cyclic vinyl triflates at 100 in 50% aqueous ethanol, buffered with triethylamine, lead exclusively to the corresponding cyclo-alkanones. Treatment of 176 with buffered CH3COOD gave a mixture of cyclohexanone (85%) and 1-cyclohexenyl acetate (15%). Mass spectral analysis of this cyclohexanone product showed that the amount of deuterium incorporation was identical to that amount observed when cyclohexanone was treated with CH3COOD under the same conditions. This result rules out an addition-elimination mechanism, at least in the case of 174, and since concerted elimination is highly unlikely in small ring systems, it suggests a unimolecular ionization and formation of a vinyl cation intermediate in the solvolysis of cyclic triflates (170). The observed solvent m values, 174 m =. 64 175 m =. 66 and 16 m =. 16, are in accord with a unimolecular solvolysis. 

The hydrolytic DKR of allyl esters has been studied as a DKR of esters. The first DKR was accomplished through Pd-catalyzed racemization and enzymatic hydrolysis of allylic acetates in a buffer solution. However, the DKR under these conditions was limited to cyclohexenyl acetates to give symmetrical palladium-allyl intermediates. Among them, 2-phenyl-2-cyclohexenyl acetate 9 was the only substrate to have been resolved with good results (81% yield, 96% ee). 

Moreover, a few chiral ferrocenylsulfur-imine ligands were investigated in the palladium-catalysed asymmetric allylic alkylation of 1,3-diphenylpropenyl acetate and cyclohexenyl acetate with dimethyl maionate (Scheme... 

Scheme 5.15 DKR of cyclohexenyl acetate to give a (-)-cyclohexenol with P. fluorescens lipase immobilized in an Si02 sol-gel matrix [62].

Acetic acid, butyl ester Acetic acid, pentyl ester Acetic acid, decyl ester Acetic acid, benzyl ester Acetic acid, benzyl ester Acetic acid, 1-cyclohexenyl ester Acetic acid, 3-cyclohexenyl ester Butyric acid, benzyl ester Phenylacetic acid, propyl ester Oleic acid, methyl ester Linoleic acid, methyl ester Linolenic acid, methyl ester Adipic acid, methyl ester Adipic acid, ethyl ester Adipic acid, diethyl ester Adipic acid, dipropyl ester Adipic acid, (methylethyl)ester Adipic acid,... 

Preparation of 4-12-cvclohexenvloxv )-stvrene. A stirred mixture of 34.36g (0.096 mole) methyltriphenylphosphonium bromide and 10.75g (0.096 mole) potassium t-butoxide in 200ml dry THF is treated drop-wise with a solution of 16.16g (0.080 mole) of 4-(2-cyclohexenyl)-benzaldehyde in 30ml THF under inert atmosphere. Once the addition of aldehyde was completed, the mixture was stirred at room temperature for another 2 hours. Ether and water were then added to the reaction mixture until clearly separated phases were obtained with no solid residue. The organic layer was separated and washed three times with water, dried over magnesium sulfate and evaporated. The resulting semi-solid was triturated in 10% ethyl acetate-hexane mixture to remove most of the triphenylphosphine and the evaporated extract was purified by preparative HPLC using hexane as eluent. This afforded 9.35g (58%) of the pure monomer, which was fully characterized by H and C-NMR as well as mass spectrometry. 

Majumdar published several aza-Claisen rearrangements of 2-cyclohexenyl-1-anilines 39 (R -R =(CH2)3, Table 2, entries 22-28) [14]. The reaction was carried out upon heating the reactant in EtOH/HCl. The corresponding 2-cy-clohexenylanilines 41 were obtained with 50 to 90% yield. The cyclization to give indole derivatives 42 could be achieved in a separate step treatment of the rearrangement products 41 with Hg(OAc)2 in a suitable alcohol in the presence of acetic acid induced formation of the tetrahydrocarbazole 42. The tricyclic products 42 were synthesized with 70-85% yield. Finally, carbazoles could be obtained after DDQ dehydrogenation. 

If an excess of sodium hydride has been used, the product contains varying amounts of the /3,7-isomer, ethyl cyclohexenyl-acetate. To ensure against the occurrence of this side reaction, a 5-10% excess of the phosphonate ester can be used. 

Acetic acid 2-hydroxy-3-oxo-3-phenylpropyl ester 3 - Acetoxy-1 -cyclohexene 17)3-Acetoxy-estr-5(10)-ene-3-one rrara-Cyclohexenyl diacetate 4-Acetyl- 1-Methylcyclohexene 3-(Azidopropenyl)benzene... 

Alkenes reacted with RuCyaq. CH3CO3H/CH3CN-CH2CI2 giving a-ketols thus cix-5-(methoxycarbonyl)-2-cyclohexenyl acetate (1) gave (2R, 35, 5R )-3-acetoxy-2-hydroxy-5-(methoxycarbonyl)-l-cyclohexanone (2) (Fig. 3.9, Table 3.2). Cortisone acetate was isolated in this way from epiandrosterone after a number of steps [179]. 

The chiral nonracemic bis-benzothiazine ligand 75 has been screened for activity in asymmetric Pd-catalyzed allylic alkylation reactions (Scheme 42) <20010L3321>. The test system chosen for this ligand was the reaction of 1,3-diphenylallyl acetate 301 with dimethyl malonate 302. A stochiometric amount of bis(trimethylsilyl)acetamide (BSA) and a catalytic amount of KOAc were added to the reaction mixture. A catalytic amount of chiral ligand 75 along with a variety of Pd-sources afforded up to 90% yield and 82% ee s of diester 303. Since both enantiomers of the chiral ligand are available, both R- and -configurations of the alkylation product 303 can be obtained. The best results in terms of yield and stereoselectivity were obtained in nonpolar solvents, such as benzene. The allylic alkylation of racemic cyclohexenyl acetate with dimethyl malonate was performed but with lower yields (up to 53%) and only modest enantioselectivity (60% ee). 

The proposed mechanism for allyhc acetoxylation of cyclohexene is illustrated in Scheme 15. Pd -mediated activation of the allyhc C - H bond generates a Jt-allyl Pd intermediate. Coordination of BQ to the Pd center promotes nucleophilic attack by acetate on the coordinated allyl ligand, which yields cyclohexenyl acetate and a Pd -BQ complex. The latter species reacts with two equivalents of acetic acid to complete the cycle, forming Pd(OAc)2 and hydroquinone. The HQ product can be recycled to BQ if a suitable CO catalyst and/or stoichiometric oxidant are present in the reaction. This mechanism reveals that BQ is more than a reoxidant for the Pd catalyst. Mechanistic studies reveal that BQ is required to promote nucleophilic attack on the Jt-allyl fragment [25,204-206]. 

Use of some other diphosphines and monophosphines is also possible for this purpose. Osborn and his coworkers reported a highly enantioselective allylic alkylation of 2-cyclohexenyl acetate with malonates by using duthixantphospholane 18a (up to 93% ee) (Equation (21)).i d7a,i7b co-workers succeeded in obtaining... 

Asymmetric nickel-catalyzed allylic alkylation with soft carbon-centered nucleophiles was reported in 1996 by Mortreux and his co-workers. Use of a catalytic amount of [Ni(cod)2] together with chiral diphosphines 138 promotes the allylic alkylation of a cyclic ester such as 2-cyclohexenyl acetate with dimethyl malonate in the presence of BSA and gives the corresponding alkylated compounds only with a moderate enantioselectivity (40% ee) (Equation (42)). 

Palladium(II) and nitrate ion with oxygen as final oxidant give an excellent yield of cyclohexenyl acetate from cyclohexene (92% at 50°C).703 The catalyst reoxidation sequence includes a palladium nitro-nitrosyl redox couple. 

Fig. 97. Solvent retained by nitrocellulose films (50/i thickness) after exposure to air at 25°C (Baelz [48]). I—Cyclohexenyl acetate, II—methyl cyclohexanone, III—diacetone alcohol, IV—cyclohexanone, V—cellosolve acetate, VI—amyl acetate-ethyl alcohol I 1, VII—amyl acetate, VIII— methyl cellosolve acetate, IX—amyl acetate-toluene 1 1, X—butyl acetate-ethyl alcohol 1 1, XI—butyl acetate, XII—cellosolve, XIII—methyl-ethyl ketone, XIV—cellosolve-toluene 1 1, XV—methyl cellosolve, XVI—ethyl acetate, XVII—acetone.

Oxidation of alkenes by Co(OAc)3 preferentially occurs at the allylic positions, yielding 2-alkenyl acetate. Oxidation of cyclohexene by Co(OAc)3 and TFA in AcOH results in the formation of cyclohexenyl acetate along with minor amounts of the corresponding allyl alcohol.550 The oxidation of ethylene by Co(TFA)3 in TFA affords ethylene glycol bis(trifluoroacetate).552... 

Oxidation of cyclohexene by peroxydisulfate in the presence of copper(II) salts results in the formation of cyclopentanecarboxaldehyde as the main product in an aqueous acetonitrile solution (equation 261), and 2-cyclohexenyl acetate in an acetic acid solution (equation 262).588,589 Reaction (261) has been interpreted as the formation of a radical cation (186) by oxidation of cyclohexene with S2Og, followed by hydrolysis of (186) to the /3-hydroxy alkyl radical (187), which is oxidized by copper(II) salts to the rearranged aldehydic product (188 equation 263).589... 

The loss of stereospecificity in the addition of bis(sulfone) anions to cyclohexenyl allylic acetates was attributed to a scrambling of the stereochemistry of the starting acetate. The ability of Pd° catalyst to effect this epimerization was confirmed in the absence of added nucleophile. This epimerization was attributed to the ability of the acetate to return to add to the ir-allyl complex via attack at the metal center (equation 177).167 This suggestion was confirmed by treatment of a preformed allylpalladium acetate dimer with CO, which resulted in cis migration of the acetate from Pd to the allyl ligand (equation 178).164... 

Loss of stereospecificity, however, has also been reported in the addition of amines. The use of homogeneous Pd° catalysts in the addition of dimethylamine to a cyclohexenyl acetate led to substantial stereochemical scrambling (equation 186). Employment of polymer-bound Pd° catalysts, however, gave complete stereospecificity via ligand addition.398 The epimerization noted in this reaction is apparently due to acetate attack at the metal center, which is prohibited by steric congestion of the metal in the polymer matrix (equation 187).398... 

The addition of sodium phenylsulfinate nucleophiles to stereodefined acyclic allylic chlorides was reported to proceed with complete overall retention of configuration, indicating that this nucleophile adds with inversion of configuration, i.e. via attack at the allyl ligand (equation 193).21S A cyclohexenyl acetate substrate also showed predominant ligand addition, but some isomeric product was also produced (equation 194).216 This loss could be due to acetate epimerization of starting material, ir-allyl epimeriza-tion by PdL2, or by attack of the sulfur at the metal, followed by reductive elimination. 

Whereas preparation of a-amino acid derivatives by asymmetric allylation of an acyclic iminoglycinate gave a modest enantioselectivity (62% ee) in an early investigation [189], the use of conformationally constrained nucleophiles in an analogous alkylation resulted in high selectivities (Scheme 8E.43) [190], With 2-cyclohexenyl acetate, the alkylation of azlactones occurred with good diastereomeric ratios as well as excellent enantioselectivities. This method provides very facile access to a variety of a-alkylamino acids, which are difficult to synthesize by other methods. When a series of azlactones were alkylated with a prochiral gem-diacetate, excellent enantioselectivities were uniformly obtained for both the major and minor diastereom-ers (Eq. 8E.20 and Table 8E.12). 

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