Search results for "Cyclohexene oxide"
showing 3 items of 3 documents
Rigid Hyperbranched Polycarbonate Polyols from CO2 and Cyclohexene-Based Epoxides
2017
Hyperbranched, multifunctional polycarbonate polyols based on CO2, cyclohexene oxide (CHO), and the “inimer” (initiator–monomer) (4-hydroxymethyl)cyclohexene oxide (HCHO) were prepared in one-pot syntheses. The related linear poly(hydroxymethyl cyclohexene carbonate) structures based on protected HCHO and postpolymerization deprotection were also synthesized as model compounds. The content of hydroxyl functionalities was adjustable for both linear and hyperbranched terpolymer systems. All CO2/epoxide polymerizations were catalyzed by the (R,R)-(salcy)-Co(III)Cl complex. The polycarbonates obtained were comprehensively investigated using various 1D and 2D NMR techniques, SEC, FT-IR, UV–vis s…
Epoxide Hydratase: Purification to Apparent Homogeneity as a Specific Probe for the Relative Importance of Epoxides among Other Reactive Metabolites
1977
Aromatic and olefinic compounds can be metabolized by microsomal monooxygenases to epoxides which chemically represent electrophilic species (for reviews, see refs. 1–5). Spontaneous binding of such epoxides to DNA, RNA, and protein has been observed (6–10). Accordingly, such metabolites have been suggested and, in some instances, shown to disturb the normal functions of cells, leading to such effects as mutagenesis (11–14), malignant transformation (15–19), or cell necrosis (20). However, aromatic and olefinic compounds are biotransformed to a vast array of metabolites (cf. refs. 21–27), possibly including a considerable number of reactive metabolites other than epoxides. The relative impo…
Radioactively labelled epoxides part II. (1) tritium labelled cyclohexene oxide, transstilbene oxide and phenanthrene 9,10-oxide
1980
Tritium labelled cyclohexene oxide, trans-stilbene oxide and phenanthrene 9,10-oxide were prepared with specific activities of 0.7 - 1.1 mCi per mmole starting with monoor diketo compounds. Tritium was introduced by reducing the ketone precursors with tritiated complex metal hydrides. The resulting alcohols were transformed to the epoxides by methods described for the unlabelled compounds. The syntheses require only two or three steps and yield cyclohexene oxide, trans-stilbene oxide and phenanthrene 9,10-oxide, important substrates for the study of epoxide hydratase and glutathione S-transferases in high radiochemical purity.