An Intravenous Pharmacokinetic Study of Cannabidiol Solutions in Piglets through the Application of a Validated Ultra-High-Pressure Liquid Chromatography Coupled to Tandem Mass Spectrometry Method for the Simultaneous Quantification of CBD and Its Carboxylated Metabolite in Plasma.

Cannabidiol (CBD) has multiple therapeutic benefits that need to be maximized by optimizing its bioavailability. Numerous formulations are therefore being developed and their pharmacokinetics need to be studied, requiring analytical methods and data from intravenous administration. As CBD is susceptible to hepatic metabolism, the requirement of any method is to quantify metabolites such as 7-COOH-CBD. We demonstrated that CBD and 7-COOH-CBD could be simultaneously and correctly quantified in piglet plasma by using an UHPLC-MS/MS technique. The validated method allowed for an accurate bioanalysis of an intravenously injected solution consisting of CBD-HPßCD complexes. The experimental pharmacokinetic profile of CBD showed multi-exponential decay characterized by a fast apparent distribution half-life (0.25 h) and an elimination half-life of two hours. The profile of 7-COOH-CBD was not linked with the first-pass metabolism, since 80% of the maximum metabolite concentration was reached at the first sampling time point, without any decrease during the period of study. A two-compartment model was optimal to describe the experimental CBD profile. This model allowed us to calculate macro-micro constants and volumes of distribution (Vss = 3260.35 ± 2286.66 mL) and clearance (1514.5 ± 261.16 mL·h-1), showing that CBD is rapidly distributed to peripheral tissues once injected and slowly released into the bloodstream.

Production challenges of tablets containing lipid excipients: Case study using cannabidiol as drug model.

The aims of this study were, firstly, to select an optimal lipid solid dispersion of cannabidiol among different lipid excipients (Gelucire® 50/13, 48/16, 44/14 and Labrasol®) and inorganic carriers (colloidal silica, Syloid® XDP and Neusilin® US2) through a screening plan. The enhancement of aqueous solubility of cannabidiol from a free-flowing powder with adequate drug content was obtained by mixing cannabidiol (20%) with Gelucire® 50/13 (40%; Gattefossé, France), both incorporated inside mesopores of mesoporous silica Syloid® XDP (40%; Grace, Germany). Secondly, we have studied the tableting properties of this selected dispersion through a Design of Experiments (DoE) by manufacturing tablets with other excipients with using a compression simulator (Styl'One® Evo, Medelpharm, France). The design of experiments included the percentage of lipid solid dispersion, of glidant, of lubricant and different compression forces. The dissolution efficiency, the drug content, the tensile strength and the ejection force were analyzed. The DoE showed that % of dispersion as well as compression forces were the main influential variables. An exit of lipid materials outside the mesopores of silica due to compression process has been highlighted, reflected by reduced tensile strength. This study showed the possibility of manufacturing tablets with lipid materials even if limitations have been highlighted. Indeed, the dispersion percentage must not exceed 27% and compression forces up to 13 kN are required to produce lipid tablets with optimal properties.

Cannabidiol aqueous solubility enhancement: Comparison of three amorphous formulations strategies using different type of polymers.

Poor aqueous solubility of terpenophenolic compound Cannabidiol (CBD) is a major issue in the widespread use of this promising therapeutic polyphenol. Moreover, choosing the appropriate strategy to overcome this challenge is time-consuming and based on trial-error processes. The amorphous form of CBD provided higher aqueous solubility as well as faster dissolution rate in comparison with crystalline CBD. Nevertheless, amorphous forms of CBD tend to recrystallize. The aim of this study was to use three different strategies based on the stabilization of the amorphous form. Cyclodextrins (CH3αCD, HPßCD and HPγCD.), mesoporous silicas (Silsol® and Syloid® AL-1FP) and water soluble polymers (Kollidon® VA64, Kollidon® 12PF and Soluplus®) were processed by using the following techniques: freeze-drying, spray-drying, subcritical carbon dioxide impregnation or hot-melt extrusion. All the obtained formulations provided complete amorphous CBD, although the drug loading depend highly of the excipients. CBD-cyclodextrin formulations, processed by freeze-drying or spray-drying, and CBD-mesoporous silica formulations, processed by subcritical CO2 or by atmospheric impregnation, provided significant increase of aqueous solubility. While the use of Kollidon® 12PF did not provided significant increased solubility within 90 min, Kollidon® VA64 has been highlighted as the excipient that exhibits the highest increase of aqueous solubility of this study. Finally, all formulations, excepted CBD-ALFP formulations, showed adequate stability within at least two months.

Three-dimensional printing technology as a promising tool in bioavailability enhancement of poorly water-soluble molecules: A review.

Poor aqueous solubility of active pharmaceutical ingredients (API) is nowadays a major issue in the pharmaceutical field. The combinatorial chemistry provides more and more API with a great therapeutic potential, but with a low aqueous solubility. Among the strategies to overcome this drawback, the use of amorphous solid dispersions (ASD), as well as the increase of surface area, is widely used. The three dimensional (3D) printing technologies appear to be innovative tools allowing the construction of any unconventional forms with different composition, structure or infill; especially by using ASD materials. This review aims to deliver notions about the different 3D printing techniques found in the literature to improve aqueous solubility of several API, namely nozzle-based method, inkjet methods and laser- based methods, as well as guide formulator in terms of formulation parameters that have to be optimized to allow the most suitable impression of innovative medicines.