Objective

Excessive mechanical stress on synovial joints causes osteoarthritis (OA) and results in the production of prostaglandin E2 (PGE2), a key molecule in arthritis, by synovial fibroblasts. However, the relationship between arthritis-related molecules and mechanical stress is still unclear. The purpose of this study was to examine the synovial fibroblast response to cyclic mechanical stress using an in vitro osteoarthritis model.

Irisin is a hormone-like myokine released from skeletal muscle during exercise. It has also been reported that irisin levels in serum and synovial fluid of knee osteoarthritis (OA) patients were negatively correlated with OA severity. We hypothesized that irisin might play a role in the cartilage homeostasis mediated by physical activity. Therefore, this study aims to explore the cross talk between skeletal muscle and cartilage tissues in human with OA mediated by the myokine irisin. Human articular OA chondrocytes were isolated, expanded and cultured in micro-mass 3-D culture system. Pellets were cultured with or without r-Irisin, and then activated by protein inhibitors of p38-MAPK signalling pathway. After one week the amount of GAG content was evaluated. Quantitative gene expression of Coll-X and Coll-II was performed. WB was utilized to detect expressions of p38-MAPK signalling pathway and Coll-X and Coll-II. In the current study, chondrocytes cultured in r-Irisin showed a significant higher GAG/DNA content compared to control (p<0.05). Moreover, r-Irisin promoted a significant increase of the expression collagen type II and decrease of collagen type X in (p<0.05). This OA chondrocytes recovery was abrogated by the p38 MAPK and ERK signalling pathways. Our observation suggests that Irisin targets chondrocytes promoting GAG content, increasing Collagen Type II and decreasing Collagen type X gene expressions. The observed OA chondrocyte recovery mediated by irisin is obtained through the inactivation of p38/ERK MAP kinase signalling cascades in vitro. This is the first study that demonstrates a cross-talk between muscle and cartilage mediated by irisin

Introduction. The concept of “bone graft expanders” has been popularised to increase the volume and biological activity of the implanted Material. HYPOTHESIS. Orthoss® granules support exogenously seeded MSCs and attract neighbouring host MSCs. Methods. In 3-D cultures’ Orthoss® granules were seeded with 2×10. 5. bone marrow MSCs/granule and maintained in MSC expansion or differentiation media for 21 days. In homing experiments’ bone autografts were placed in close proximity to Orthoss®. Scaffold colonisation and MSC differentiation were assessed by confocal microscopy’ standard electron microscopy’ and energy-dispersive X-ray spectroscopy. Results. Long-term incubation of MSC/scaffold resulted in formation of multiple cell-matrix layers lining the scaffold pores as well as outer surfaces. MSC differentiation to osteoblasts was evident as strong deposition of Calcium and Phosphorus was detected in both MSC expansion and osteogenic conditions. Cell egress experiments demonstrated the migration of cells from neighbouring autografts and their attachment and re-settlement on Orthoss®. Discussion & Conclusions. Orthoss® scaffolds support MSC attachment’ growth and osteogenic differentiation whereas resident bone subpopulations can rapidly migrate towards’ attach’ and expand on them. These results indicate that Orthoss® can serve as a graft expander for repairing large bone defects in trauma patients

After the embryonic period, notochord remnants persist inside the intervertebral disc (IVD), where they give rise to the nucleus pulposus. Notochordal cells (NTCs) gradually disappear during maturation. This phenomenon is correlated with onset of disc degeneration. The objective of this study was to design a protocol for the isolation of NTCs to study his role in IVD regeneration. Lumbar IVDs from immature rats were either enzymatically dissociated or mechanically taken out or cells isolation. Cells RNA extraction for PCR analysis was performed to assay Sonic and Indian Hedgehog (Ihh and Shh) and his receptor Patched (Ptc) expression. NTCs were readily detectable in culture as large vacuolated “physalipherous” cells, with the enzymatic method. The cells isolated mechanically were enable to grow in monolayer while grown 2 weeks in a 3-D pellet culture. Ihh and Ptc was expressed in the cells isolated with both method, while Shh was expressed only in the cells isolated through the mechanical method. Our findings show that the better way to isolate a pure population of NTCs is a mechanical extraction from a immature IVD. This is a first step in order to study his role for the regeneration of IVD