Ceapro Inc. announced that results from a collaborative project with University of Alberta researchers have been accepted for publication in the Journal of Supercritical Fluids in an article titled Preparation of PGX-dried gum arabic and its loading with coQ10 by adsorptive precipitation, authored by Couto R., Wong E, Seifried B, Moquin P and Temelli F. The main objective of this study was to investigate the preparation of coenzyme Q10 (coQ10) loaded gum arabic (GA) using the Pressurized Gas eXpanded (PGX) liquid technology and adsorptive precipitation processes. It was found that PGX could effectively dry, purify and increase the surface area of GA. Using adsorptive precipitation, coQ10 was homogenously loaded on the large surface area of PGX processed GA leading to the formation of a new chemical complex (coQ10-iGA) that, upon solubilization into water, formed stable aqueous dispersions of coQ10. This study allowed Ceapro’s scientists to compare coQ10-iGA with the previous study where coQ10 was loaded on PGX-processed oat ß-glucan leading to the formation of coQ10-iBG. The coQ10-iBG was the complex that won the 2018 award for most innovative raw material at the Cosmetic 360 salon in Paris. Given similarly obtained stable aqueous dispersions of coQ10 upon solubilization of both coQ10-iGA and coQ10-iBG in water, this study confirms that PGX processing shows great potential for the drying of biodegradable and water-soluble biopolymers and their loading with lipid soluble bioactives as delivery systems. Other studies using different carriers like alginate and chitosan have also been conducted and will be the subject of future publications. Ceapro has conducted research on various biopolymer samples from different sources. These studies conducted in collaboration with Dr. Feral Temelli’s team at University of Alberta further demonstrate the versality of PGX and adsorptive precipitation technologies. Results of these studies illustrate the potential to dry, purify, micronize, functionalize and load proteins, peptides, and polysaccharides that can lead to the development of highly potent bioactive delivery systems with desirable characteristics.