Nanocrystal-chitosan particles for intra-articular delivery of disease-modifying osteoarthritis drugs.

Osteoarthritis is the most common chronic joint disease and a major health care concern due to the lack of efficient treatments. This is mainly related to the local and degenerative nature of this disease. Kartogenin was recently reported as a disease-modifying osteoarthritis drug that promotes cartilage repair, but its therapeutic effect is impeded by its very low solubility. Therefore, we designed a unique nanocrystal-chitosan particle intra-articular delivery system for osteoarthritis treatment that merges the following formulation techniques: nanosize reduction of a drug by wet milling and spray drying. The intermediate formulation (kartogenin nanocrystals) increased the solubility and dissolution rates of kartogenin. The final drug delivery system consisted of an easily resuspendable and ready-to-use microsphere powder for intra-articular injection. Positively charged chitosan microspheres with a median size of approximately 10 µm acted as a mothership drug delivery system for kartogenin nanocrystals in a simulated intra-articular injection. The microspheres showed suitable stability and a controlled release profile in synovial fluid and were nontoxic in human synoviocytes. The cartilage retention skills of the microspheres were also explored ex vivo using cartilage. This drug delivery system shows promise for advancement to preclinical stages in osteoarthritis therapy and scale-up production.

Microfluidic preparation of various perfluorocarbon nanodroplets: Characterization and determination of acoustic droplet vaporization (ADV) threshold.

Over the last two decades, liquid perfluorocarbon nanodroplets (PFC-NDs), also known as Phase Change Contrast Agents (PCCAs), that are capable of vaporizing into gaseous echogenic microbubbles via an external stimulus, have gained much attention for diagnostic and therapeutic applications. In the present work, a microfluidic platform is evaluated for the preparation of various size-controlled nanodroplets. Here, two major lines of investigations were carried out. The first was to define the microfluidic device settings for the preparation of nanodroplets depending on the nature of the encapsulating shell such as lipids, fluorinated surfactants and PLGA biopolymers as well as the liquid perfluorocarbon core (perfluoropentane, perfluorohexane). Specifically, the effect of the microfluidic system parameters, such as total flow rate and flow rate ratio on PFC-NDs attributes including size and uniformity was assessed. Secondly, a custom-made set-up, based on echogenicity signals from produced bubbles, was designed and successfully applied to determine the Acoustic Droplet Vaporization (ADV) threshold of PFC-NDs. Finally, the influence of various formulation parameters on the vaporization outcome was investigated depending on the PFC type and the encapsulating shell composition (soft versus hard shells). This study indicates the usefulness of this novel formulation platform enabling the rapid design and optimization of narrowly dispersed nanodroplets at a reliable yield and ultimately accelerate nanomedicines development.