Abstract
Cartilage-bone interactions play a critical role in joint diseases and the osteochondral junction has been identified as a locus of osteoarthritis development. However, it is challenging to study osteochondral (OC) interaction in vitro, since cartilage and bone require very different environments. We developed a new medium-to-high throughput osteochondral microphysiological system bioreactor to culture biphasic native or engineered constructs and that can be used to study any musculoskeletal tissue interfaces. We developed engineered constructs from hMSCs on a porous polymeric matrix with a gradient in pore size to assess the supportive effect of the local topology on cartilaginous and osseous differentiation. Furthermore, we developed a triphasic, vascualized osteochondral constructs based on porous polycaprolactone and methacrylated gelatin scaffolds to study the specific effects of vasculature on cartilage and bone. We also cultured native OC tissues from postmenopausal women, exposing either cartilage or bone to sex hormones studying their protective effects. Finally, our bioreactor is being implemented for use on the International Space Station to study countermeasures against microgravity bone loss. Overall, our bioreactor maintains media separation for in vitro culture and engineering of OC tissues and constructs of progressively greater complexity, and it preserves the possibility of direct cartilage-bone crosstalk opening new opportunities to study interactions across the osteochondral junction.
