Abstract
Introduction and Objective
Osteoarthritis (OA) is the most common inflammatory and degenerative joint disease. Mesenchymal Stromal Cells (MSCs), with their chondro-protective and immune-regulatory properties, have been considered as a new approach to treat OA. Considering the risk of cell leakage outside the articular space and the poor survival rate after intra-articular (IA) injection, we hypothesized that cell encapsulation in cytoprotective hydrogels could overcome these limitations and provide cells with a suitable 3D microenvironment supporting their biological activity. We previously generated micromolded alginate particles (diameter 150 μm) and demonstrated the long-term viability of microencapsulated MSCs isolated from human adipose tissue (hASCs). Encapsulated cells maintained their in vitro ability to sense and respond to a pro-inflammatory environment (IFN-γ/TNF-α or synovial fluids from OA patients) by secreting PGE2, IDO, HGF and TGF-β. In this study, we evaluated the anti-OA efficacy of these microencapsulated hASCs in a post-traumatic OA model in rabbits.
Materials and Methods
OA was surgically induced by anterior cruciate ligament transection (ACLT)-mediated destabilization of the right knee in rabbits (n=24). Eight weeks after surgery, destabilized joints were injected (IA, 26G needle) with 200 μL of either PBS, blank microparticles, non-encapsulated or microencapsulated cells (5×105 cells). Six weeks after injection, rabbits were euthanized and all destabilized (right) and sham-operated (left contralateral) joints were dissected and analyzed for OA severity. Tibial subchondral bone histomorphometric parameters were measured by quantitative micro-computed tomography (micro-CT). Histological sections of samples were analyzed after Safranin-O staining and quantitatively assessed according to a modified Osteoarthritis Research Society International (OARSI) scoring system. Immunohistochemical detection of NITEGE was performed to assess the extracellular matrix degradation.
Results
Micro-CT analysis of destabilized joints confirmed that the rabbit ACLT significantly affected the tibial subchondral bone architecture as early as eight weeks, as revealed by significant changes of the subchondral bone parameters of operated joints compared to the sham operated joints. In particular, destabilized joints exhibited a Bone Volume/Tissue Volume ratio (BV/TV) ranging from 53.4% to 56.6%, compared to a mean BV/TV of 65.4% for sham operated joints. All destabilized joints also exhibited a significantly increased modified OARSI score, ranging from 7.4±0.4 for those injected with encapsulated cells to 8.9±0.2 for those injected with PBS, as compared to 4.8±0.4 for sham-operated joints. Of interest, we identified a slight, while not significant, reduction of the severity of OA lesions after injection of microencapsulated cells using the modified OARSI scoring. Finally, semi-quantitative analysis of NITEGE immunostaining revealed a significant increase in all destabilized joints that were injected with PBS or blank microparticles, in comparison with sham ones. On the contrary, NITEGE immunostaining in destabilized joints that were injected with non-encapsulated or encapsulated hASC revealed a significant reduced NITEGE immunostaining, indicating a decreased matrix degradation.
Conclusions
Our data suggest that the microencapsulated hASCs exerted their anti-OA properties after IA injection in rabbit knees, as evidenced by the tendency toward a reduced modified OARSI score, and most importantly a significant reduction in NITEGE immunostaining associated matrix degradation. Further studies are now warranted to investigate the anti-OA efficacy of microencapsulated hASCs in the long-term.
