Separation of polyprenol and dolichol by monolithic silica capillary column chromatography

Separation of polyprenols from Ginkgo biloba leaves by a nano silica-based adsorbent containing silver ions

Polyprenols extracted from Ginkgo biloba leaves is a kinds of unsaturated compound containing double bonds. Traditionally, the separation methods for the polyprenols are lack of selectivity and their separation efficiency are low. We synthesized two kinds of functional nano-silica containing silver ions materials (AgTCM and AgTCN) which have selectivity for unsaturated compounds to separate Ginkgo biloba leaves polyprenols for the first time. AgTCN displays exceptionally high selectivity for polyprenols and high stability under extended heat and light exposure, while silver is virtually immobile during solvent elution. Importantly, the exceptional stability of AgTCN gives rise to much higher polyprenols recovery than conventional silica gel during the chromatographic elution. In addition, we found that the adsorption of polyprenols onto the AgTCN conforms to pseudo-second-order kinetic model and AgTCN has strong affinity with polyprenols by analyzing Langmuir, Freundlich, Temkin-Pyzhev, and Dubinin-Radushkevich isotherms. The calculation results of thermodynamic parameters demonstrate that decrease of temperature in favor of increasing the adsorbing capacity of polyprenols onto the AgTCN, and the adsorption process of which is exothermic reaction. Our results pave the way for the novel separation methods of polyprenols from Ginkgo biloba leaves.

The history and recent advances in research of polyprenol and its derivatives

The reduction pathway leading to the formation of dolichol was clarified in 2010 with the identification of SRD5A3, which is the polyprenol reductase. The finding inspired us to reanalyze the length of the major chain of polyprenol and dolichol from several plant leaves, including mangrove plants, as well as from animal and fish livers by 2D-TLC. Polyprenol- and dolichol-derived metabolites such as polyprenylacetone and epoxydolichol were found together with rubber-like prenol. This review focuses on analyses of polyprenol and its derivatives, including recently found epoxypolyprenol and polyprenylacetone. Attention has also been paid to the chromatographic behavior of rubber-like prenol on TLC.

Application of monolithic (continuous bed) chromatographic columns in phytochemical analysis

One and a half decade passed since the pioneering work on synthesis and application of non-particulate monolithic stationary phases for liquid chromatography was published by S. Hjertén et al. [S. Hjertén, J.L. Liao, R. Zhang, J. Chromatogr. 473 (1989) 273]. This technique attracted much interest and effort of the researchers developing chromatographic methods and designing chromatographic stationary phases due to several generic qualities of the monolithic (continuous bed) technique. Advantages include: flexibility of the technique in sense of chemistries and functional compositions of the resultant stationary phases; low separation impedance (ratio of pressure drop and efficiency) of monolithic columns; compatibility with micro and nanoformat separations; low time and labour consumption and cost-efficiency. Not surprisingly, these materials attracted interest from phytochemists as plants constitute a complex matrix. However to date, not many successful studies were published in the area of monolithic materials for solving plant metabolomics problems or substituting common particulate materials with monolithic stationary phases in phytochemical analysis. This paper provides an overview.