Epoxides derived from cyclohexenes

The potential of such reaction sequences for the generation of molecular diversity was also demonstrated by the synthesis of a library of heterocycles. Epoxide ring-opening with hydrazine and subsequent condensation with (3-diketones or other bifunctional electrophiles gave rise to a variety of functionalized heterocyclic structures in high purity [34]. A selection based on the substrate derived from cyclohexene oxide is shown in Scheme 12.12. 

The preparation of Pans-1,2-cyclohexanediol by oxidation of cyclohexene with peroxyformic acid and subsequent hydrolysis of the diol monoformate has been described, and other methods for the preparation of both cis- and trans-l,2-cyclohexanediols were cited. Subsequently the trans diol has been prepared by oxidation of cyclohexene with various peroxy acids, with hydrogen peroxide and selenium dioxide, and with iodine and silver acetate by the Prevost reaction. Alternative methods for preparing the trans isomer are hydroboration of various enol derivatives of cyclohexanone and reduction of Pans-2-cyclohexen-l-ol epoxide with lithium aluminum hydride. cis-1,2-Cyclohexanediol has been prepared by cis hydroxylation of cyclohexene with various reagents or catalysts derived from osmium tetroxide, by solvolysis of Pans-2-halocyclohexanol esters in a manner similar to the Woodward-Prevost reaction, by reduction of cis-2-cyclohexen-l-ol epoxide with lithium aluminum hydride, and by oxymercuration of 2-cyclohexen-l-ol with mercury(II) trifluoro-acetate in the presence of ehloral and subsequent reduction. ... 

The vinyloxirane reaction was later extended to methylidene cyclohexene oxide and to related meso derivatives [53]. The effects of the diastereomeric ligands 42 and 43 (Fig. 8.5), derived from (S)-binaphthol and (S, S)- or (R, R)-feis-phenylethyl-amine respectively, were investigated. In the case of kinetic resolution of racemic methylidene cyclohexane epoxide 45 with Et2Zn, ligand 42 produced better yields, regioselectivity, and enantioselectivity than 43 (Scheme 8.27). 

Cleavage of epoxides. As with simpler haloboranes, these reagents cleave epoxides of cycloalkenes to give, after nonoxidative workup, halohydrins in 65-90% yield. When carried out at -78 to -100°, the cleavage can show high en-antioselectivity. Thus the halodiisopinocampheylboranes derived from (+ )-pinene react with the oxide of cyclohexene or of cyclopentene to furnish (1R,2R) halo-... 

Epoxidation. In the presence of catalytic amounts of 18-crown-6 and an acyl chloride, KO, can effect epoxidation of alkenes and of some polycyclic arenes derived from phenanthrene. The most effective acyl chlorides are phosgene and benzoyl chloride. The highest yields of epoxides are formed from fran,v-stilbene (89%) and cyclohexene (80%). The 9,10-epoxide of phenanthrene is obtained in 38% yield. 

They found that the erythrolthreo-% i,cX N Xtj is X-substituent dependent, acting through H-bonding, which was demonstrated by the TFDO Ic epoxidation of 73. An example of cyclohexene epoxidation by dioxiranes derived from various ketones grafted on solid supports has also appeared <1996MI273>. Shi and co-workers reported <1996JA9806> excellent ee s of asymmetric epoxidation of different /ra t-olefms by fructose-derived ketones 74 before then, only low enantioselectivities (9-20%) have been reported on this type of reaction. 

Methylcyclohexene oxide (equation 118) provides a useful model system for mechanistic discussion. It is important that no 2-methylcyclohexanone is formed, since this rules out carbenium ion pathways. The major product is derived from the bromohydrin (276), formed by bromide attack at the tertiary center (followed by chair-chair interconversion), but care must be taken to avoid overinterpretation of this observation. Thus, if the bromohydrins are rapidly interconverting via the epoxide, the product distribution would be determined not only by the equilibrium ratio of (276) and (277), but also by the respective rate constants for rearrangement to (230) and (215). Although cyclohexene bromohydrin is immediately converted to the epoxide by treatment with Bu"Li in benzene," the possible effect of HMPA on the bro-mohydrin(salt)/epoxide equilibrium is not known. The rearrangement rates would be Br (276) > Br ... 

Stereoselective epoxidations of substituted cyclohexenes with in situ generated dioxiranes have been studied <94TL1577>. The most favorable trans/cis selectivities have been achieved using dioxiranes derived from sterically hindered ketones (Scheme 26). 

S)-(-)-CITRONELLOL from geraniol. An asymmetrically catalyzed Diels-Alder reaction is used to prepare (1 R)-1,3,4-TRIMETHYL-3-CYCLOHEXENE-1 -CARBOXALDEHYDE with an (acyloxy)borane complex derived from L-(+)-tartaric acid as the catalyst. A high-yield procedure for the rearrangement of epoxides to carbonyl compounds catalyzed by METHYLALUMINUM BIS(4-BROMO-2,6-DI-tert-BUTYLPHENOXIDE) is demonstrated with a preparation of DIPHENYL-ACETALDEHYDE from stilbene oxide. A palladium/copper catalyst system is used to prepare (Z)-2-BROMO-5-(TRIMETHYLSILYL)-2-PENTEN-4-YNOIC ACID ETHYL ESTER. The coupling of vinyl and aryl halides with acetylenes is a powerful carbon-carbon bond-forming reaction, particularly valuable for the construction of such enyne systems. 

Acetylenes, few of which are biologically active, have also been isolated from microorganisms and marine organisms, such as the antifungal acetylenic cyclohexene-epoxide derivative asperpentyn isolated from Aspergilus and dactylyne, an acetylenic dibromochloro-ether, isolated from sea hare. Dactylyne was shown to be a very potent inhibitor of drug metabolism... 

Ni(II) complexes of cyclam and oxocyclam derivatives catalyze the epoxidation of cyclohexene and various aryl-substituted alkenes with PhIO and NaOCl as oxidants, respectively. In the epoxidation catalyzed by the Ni(II) cyclam complex using PhIO as a terminal oxidant, the high-valent nickel-oxo complexes (e.g., LNi -0, LNi=0, LNi -0-I-Ph, or LNi -0-Ni L) have been proposed as the active oxidant (92). In the reaction, E olefins are more reactive than the corresponding Z isomers, and a strong correlation was observed between the electron-donating effect of the para substituents in styrene and the initial reaction rate (91). Isotope labeling studies have shown that the epoxide oxygen is derived from PhIO. 

Another possibility for the formation of free radical species from hypochlorite is through its reactions with transition metal ions. Thus, Guilmet and Meunier (1980) reported a manganese-promoted epoxidation of olefins such as styrene (Equation 5.13) and cyclohexene in a two-phase dichloromethane-water solvent mixture. The epoxide oxygen was derived from HOCl, not from air, but no mechanistic details were speculated upon. Further evidence needs to be obtained on the possibility of free-radical reactions in water and wastewater chlorination. 

Lithium amides derived from secondary amines like lithium diisopro-pylamide (1) appear to be strong enough bases to deprotonate epoxides, ketones, etc. However, when 1, which is a non-chiral base, deprotonates the non-chiral epoxide cyclohexene oxide (2), equal amounts of the two enantiomeric products (5)- and (/ )-cyclohex-2-enol (3) are formed in the abstraction of a proton from carbon 2 and 5, respectively, with accompanying opening of the epoxide ring (Scheme 1). Thus, none of the two enantiomeric products is formed in enantiomeric excess (ee), i.e., the reaction shows no stereoselectivity (Scheme 1). 

Reaction of the alkenyl carbene complex 117, derived from tetra-O-benzyl-aldehydo-D-hbose, with cyclohexene oxide in the presence of [Cp2TiCl]2 gave the oxa-trans-decalin complex 118, together with a smaller proportion of the epimer at the asterisked carbon. This work was extended to the use of sugar epoxide 119 and the carbene complex 120 to give the dioxabicyclo-system 121. ... 

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