Abstract
The supercritical antisolvent-(SAS) technique serves as an environmentally benign processing method that effectively enhances the pharmacokinetic properties of poorly water-soluble drugs. Nevertheless, the existing supercritical fluid technology and processing methodologies remain underdeveloped, presenting significant barriers to large-scale industrial implementation. To overcome these limitations, a coaxial nozzle and its associated auxiliary apparatus were engineered. Taking curcumin as the research object, using polyvinylpyrrolidone-(PVP) as the polymer carrier, and ethanol and acetone as the organic solvents, curcumin/PVP coprecipitated particles were synthesized via the SAS process. A detailed examination was conducted to evaluate the influence of key processing parametersincluding acetone/ethanol-(Ac/EtOH) volume ratio, curcumin/PVP mass ratio, temperature, pressure, and solution concentrationon the particle size and distribution of the resulting coprecipitates. The coprecipitate was characterized by various characterization methods. The findings reveal that the SAS process effectively generated amorphous curcumin/PVP coprecipitates with a submicron-scale particle diameter of 337 ± 47 nm. These findings confirm the great potential of the SAS method in the production of polymer-drug composite systems.