Oxidation Study of Oleocanthal and Oleacein Induced by Oxone.

A selective Oxone-induced oxidation of oleocanthal and oleacein, the two main secoiridoids of olive oil, to their bis-oxidized products is described. This protocol is based on a Baeyer-Villiger mechanism and the concentration of Oxone in the final solution. The bis-oxidation of the aldehydic compounds could be extended for the synthesis of various semisynthetic analogs. The obtained acids exhibit strong antioxidant activity, being efficient free radical scavengers.

Gentiopicroside-An Insight into Its Pharmacological Significance and Future Perspectives.

Gentiopicroside (GPS) is a leading component of several plant species from the Gentianaceae botanical family. As a compound with plenty of biological activities and a component of herbal drugs, GPS has an important role in the regulation of physiological processes in humans. The results of recently published scientific studies underline a meaningful role of this molecule as an active factor in metabolic pathways and mechanisms, which may have an influence in the treatment of different diseases, including digestive tract disorders, malignant changes, neurological disorders, microbial infections, bone formation disorders, inflammatory conditions, and others. This review aims to collect previously published reports on the biological properties of GPS as a single compound that were confirmed by in vitro and in vivo studies, and to draw attention to the newly discovered role of this bitter-tasting secoiridoid. Thanks to these properties, the research on this substance could be revisited.

Oxidized Forms of Olive Oil Secoiridoids: Semisynthesis, Identification and Correlation with Quality Parameters.

Secoiridoids is the prominent chemical class of olive oil polar constituents and are characterized by significant biological properties. They are abundant in different chemical forms and relatively high concentrations compared to other components, while prone to oxidation due to their chemical motif. In recent years, oxidized derivatives of secoiridoids have been reported, either as natural constituents of olive oil or as components which are gradually formed in all stages of its production and storage. The mono-oxidized forms of oleocanthal and oleacein named as the respective acids have been recently isolated from olive oil and unambiguously structurally characterized. Other oxidized forms of elenolic acid or more complex secoiridoids, such as those of oleuropein and ligstroside aglycones are also sporadically mentioned in the literature. No further information is provided since they have not been isolated in pure form in order to be accurately identified. Most of the time, they are generally referred as oxidized forms of the parent compounds and commonly identified based on mass spectrometric data. In the current study, the semi-synthesis of the main oxidized olive oil secoiridoids, i.e., oleocanthalic acid, oleaceinic acid, EDA acid, carboxylic form of elenolic acid, carboxylic form of ligstroside aglycon, and carboxylic form of oleuropein aglycon is described starting from the corresponding aldehydic derivatives, using SeO2/H2O2 as oxidative agents. Furthermore, their presence in a number of Greek olive oils was investigated as well, as possible correlation thereof with quality parameters.

Development and physicochemical characterization of nanoliposomes with incorporated oleocanthal, oleacein, oleuropein and hydroxytyrosol.

Oleocanthal, oleacein, oleuropein and hydroxytyrosol comprise characteristic polyphenols of olive with high biological value. However, stability problems hinder their further investigation. Thus, in the present study they were incorporated in nanoliposomes by thin film hydration method. The particles sizes, PDI, zeta-potential and physicochemical stabilities of nanoliposomes were evaluated by light scattering methods while FTIR, XRD, TGA and DSC methods were carried out for further physicochemical characterization. Their micromorphology was illustrated by negative-staining TEM and Cryo-TEM, revealing well-dispersed round-shaped vesicles. According to in vitro release studies, oleocanthal and oleacein were rapidly released in a higher percentage than oleuropein and hydroxytyrosol and compatible with the Ritger-Peppas model release mechanism while only oleuropein liposomes were governed by anomalous diffusion of non-Fickian diffusion. Antioxidant assays showed that nanoliposomes presented comparable activity with pure compounds enabling them as suitable carriers for the delivery of olive active biophenols in the human organism.