Intrinsic Permeation and Anti-Inflammatory Evaluation of Curcumin, Bisdemethoxycurcumin and Bisdemethylcurcumin by a Validated HPLC-UV Method.

Curcumin shows anti-inflammatory activity, and it has been widely investigated for neurodegenerative diseases, adjuvant treatment in AIDS and antitumor activity against different tumors, among other activities. The goal of this work was to evaluate the capacity of curcumin and its derivatives (bisdemethoxycurcumin and bisdemethylcurcumin) in preventing the irritant effects of topically applied xylol and to assess the intrinsic capacity of curcuminoids in permeating human skin by ex vivo permeation tests. Its secondary goal was to validate an HPLC method to simultaneously determine the curcuminoids in the samples from the ex vivo permeation studies and drug extraction from the skin. Curcuminoid quantification was performed using an RP-C18 column, at isocratic conditions of elution and a detection wavelength of 265 nm. The method was specific with a suitable peak resolution, as well as linear, precise, and accurate in the range of 0.195-3.125 µg/mL for the three curcuminoids. Bisdemethylcurcumin showed the greatest permeation through the human skin, and it was the curcuminoid that was most retained within the human skin. The anti-inflammatory activity of the curcuminoids was evaluated in vivo using a xylol-induced inflammation model in rats. Histological studies were performed to observe any changes in morphology at the microscopic level, and these three curcuminoids were found to be respectful within the skin structure. These results show that these three curcuminoids are suitable for anti-inflammatory formulations for dermal applications, and they can be properly quantified using HPLC-UV.

Voltammetric and electrogeneration approaches for the assessment of the oxidative drug metabolism.

In this paper, electrochemical (EC) methods have been proposed to evaluate the oxidative behavior of drugs as rapid, simple, and cheap strategies to predict some metabolic features. Various commercial drugs belonging to different therapeutic families have been assayed to deal with a wide variety of biotransformations and to cover different metabolism extents. First, differential pulse voltammetry has been applied to evaluate the oxidative behavior of drugs. Voltammetric assays have demonstrated to be highly efficient to predict the metabolism extent from the current intensity data. The second objective of this work has been the comparison of metabolite profiles from both EC and in vitro methods based on liver microsome assays. The resulting samples have been analyzed by reversed-phase liquid chromatography mode using a core-shell column and UV detection. Chromatographic methods have been established for each particular drug and its metabolites using 0.1% (v/v) formic acid aqueous solution and methanol (MeOH) as the components of the mobile phase. Drug oxidation products from both EC- and microsome-based methodologies have been compared in terms of variety and percentage from the corresponding chromatographic profiles. In general, most of the metabolites occurring in vitro have also been reproduced in the EC runs. Besides, it has been found that compositional profiles from EC experiments are dependent on experimental variables such as pH and potential. In general, acid (pH 2) and basic (pH 10) conditions and too high potentials can contribute to the generation of oxidation artifacts which differ from metabolites while milder potentials and neutral pH values may reproduce more accurately the microsome patterns. The proposed methodology is suitable for a first study of the oxidative behavior of molecules that can be related to relevant metabolic properties. The obtained information could be of great interest to prioritize or discard compounds, as a first screening, on the research of drug candidates.

Broadening the scope of high structural dimensionality nanomaterials using pyridine-based curcuminoids.

We present a new heteroditopic ligand (3pyCCMoid) that contains the typical skeleton of a curcuminoid (CCMoid) decorated with two 3-pyridyl groups. The coordination of 3pyCCMoid with ZnII centres results in a set of novel coordination polymers (CPs) that display different architectures and dimensionalities (from 1D to 3D). Our work analyses how synthetic methods and slight changes in the reaction conditions affect the formation of the final materials. Great efforts have been devoted toward understanding the coordination entities that provide high dimensional systems, with emphasis on the characterization of 2D materials, including analyses of different types of substrates, stability and exfoliation in water. Here, we foresee the great use of CCMoids in the field of CPs and emphasize 3pyCCMoid as a new-born linker.