Chemo enzymatic synthesis of Rengyol and Isorengyol

Effect of the Dried Flowers of Campsis grandiflora on Stagnant Blood Syndrome

Dried flower of Campsis grandiflora ( Bignoniaceae), known as ryoushouka in Japanese, is a traditional Chinese medicine used to treat stagnant blood, contusion, pruritus, and gynecopathy such as menstrual and menopausal disorders. In the present study, we evaluated the stagnant blood flow (BF) improvement effect of the methanol extract (CG) of dried flowers of C. grandiflora using an in vivo assay, in a continuing effort to improve peripheral circulatory disturbance using natural sources. We used the assay system to monitor a decrease in BF in the tail vein microcirculation of mice subjected to sensitization with hen-egg white lysozyme. Bioassay-guided fractionation of the CG led to the isolation of apigenin (1), acteoside (2), cleroindicin B (3), rengyol (4), and isorengyol (5). Apigenin (1) and acteoside (2) were identified as active compounds as they exhibited significant stagnant BF improvement effect in the peripheral circulation. This study proved the positive effect of ryoushouka against stagnant blood syndrome.

Comparison of Fruits of Forsythia suspensa at Two Different Maturation Stages by NMR-Based Metabolomics

Forsythiae Fructus (FF), the dried fruit of Forsythia suspensa, has been widely used as a heat-clearing and detoxifying herbal medicine in China. Green FF (GF) and ripe FF (RF) are fruits of Forsythia suspensa at different maturity stages collected about a month apart. FF undergoes a complex series of physical and biochemical changes during fruit ripening. However, the clinical uses of GF and RF have not been distinguished to date. In order to comprehensively compare the chemical compositions of GF and RF, NMR-based metabolomics coupled with HPLC and UV spectrophotometry methods were adopted in this study. Furthermore, the in vitro antioxidant and antibacterial activities of 50% methanol extracts of GF and RF were also evaluated. A total of 27 metabolites were identified based on NMR data, and eight of them were found to be different between the GF and RF groups. The GF group contained higher levels of forsythoside A, forsythoside C, cornoside, rutin, phillyrin and gallic acid and lower levels of rengyol and β-glucose compared with the RF group. The antioxidant activity of GF was higher than that of RF, but no significant difference was observed between the antibacterial activities of GF and RF. Given our results showing their distinct chemical compositions, we propose that NMR-based metabolic profiling can be used to discriminate between GF and RF. Differences in the chemical and biological activities of GF and RF, as well as their clinical efficacies in traditional Chinese medicine should be systematically investigated in future studies.

Innate and guided C-H functionalization logic

The combustion of organic matter is perhaps the oldest and most common chemical transformation utilized by mankind. The generation of a C-O bond at the expense of a C-H bond during this process may be considered the most basic form of C-H functionalization. This illustrates the extreme generality of the term "C-H functionalization", because it can describe the conversion of literally any C-H bond into a C-X bond (X being anything except H). Therefore, it may be of use to distinguish between what, in our view, are two distinct categories of C-H functionalization logic: "guided" and "innate". Guided C-H functionalizations, as the name implies, are guided by external reagents or directing groups (covalently or fleetingly bound) to install new functional groups at the expense of specifically targeted C-H bonds. Conversely, innate C-H functionalizations may be broadly defined as reactions that exchange C-H bonds for new functional groups based solely on natural reactivity patterns in the absence of other directing forces. Two substrates that illustrate this distinction are dihydrojunenol and isonicotinic acid. The C-H functionalization processes of hydroxylation or arylation, respectively, can take place at multiple locations on each molecule. Innate functionalizations lead to substitution patterns that are dictated by the inherent bias (steric or electronic) of the substrate undergoing C-H cleavage, whereas guided functionalizations lead to substitution patterns that are controlled by external directing forces such as metal complexation or steric bias of the reagent. Although the distinction between guided and innate C-H functionalizations may not always be clear in cases that do not fit neatly into a single category, it is a useful convention to consider when analyzing reactivity patterns and strategies for synthesis. We must emphasize that although a completely rigorous distinction between guided and innate C-H functionalization may not be practical, we have nonetheless found it to be a useful tool at the planning stage of synthesis. In this Account, we trace our own studies in the area of C-H functionalization in synthesis through the lens of "guided" and "innate" descriptors. We show how harnessing innate reactivity can be beneficial for achieving unique bond constructions between heterocycles and carbonyl compounds, enabling rapid and scalable total syntheses. Guided and innate functionalizations were used synergistically to create an entire family of terpenes in a controlled fashion. We continue with a discussion of the synthesis of complex alkaloids with high nitrogen content, which required the invention of a uniquely chemoselective innate C-H functionalization protocol. These findings led us to develop a series of innate C-H functionalization reactions for forging C-C bonds of interest to the largest body of practicing organic chemists: medicinal chemists. Strategic use of C-H functionalization logic can have a dramatically positive effect on the efficiency of synthesis, whether guided or innate.