Abstract
The enthesis is a specialised zonal tissue interface between tendon and bone, essential for adequate force transmission and composed by four distinct zones, namely tendon, fibrocartilage, mineralized fibrocartilage and bone. Following injuries and surgical repair, the enthesis is often not reestablished and so far, traditionally used tissue substitutes have lacked to reproduce the complexity of the native tissue. In this work, we hypothesised that a collagen-based three-layer scaffold that mimic the composition of the enthesis, in combination with bioactive molecules, will enhance the functional regeneration of the enthesis. A three-layer sponge composed of a tendon-like layer (collagen I), a cartilage-like layer (collagen II) and a bone-like layer (collagen I and hydroxyapatite) was fabricated by an iterative layering freeze-drying technique. Scaffold porosity and structural continuity at the interfaces were assessed through SEM analysis. Bone-marrow derived stem cells (BMSCs) were seeded by syringe vacuum assisted technique on the scaffold. Scaffolds were cultured in basal media for 3 days before switching to differentiation media (chondrogenic, tenogenic and osteogenic). BMSCs metabolic activity, proliferation and viability were assessed by alamarBlue, PicoGreen and Live/Dead assays. At D21 the scaffolds were fixed, cryosectioned and Alizarin Red and Alcian Blue stainings were performed in order to evaluate BMSC differentiation towards osteogenic and chondrogenic lineage. The presence of collagen I and tenascin in the scaffolds was evaluated by immunofluorescence staining at D21 in order to assess tenogenic differentiation of BMSCs. Subsequently, the cartilage-like layer was functionalized with IGF-1, seeded with BMSCs and cultured in basal media up to D21. Structural continuity at the interfaces of the scaffolds was confirmed by SEM and scaffold porosity was assessed as >98%. The scaffolds supported cell proliferation and infiltration homogeneously throughout all the layers up to D21. Osteogenic differentiation of BMSC selectively in the bone-like layer was confirmed by Alizarin red staining in scaffolds cultured in basal and osteogenic media. Alcian blue staining revealed the presence of proteoglycans selectively in the cartilage-like layer in scaffolds cultured in chondrogenic media but not in basal media. Increased expression of the tenogenic markers collagen I and tenascin were observed in the tendon-like layer of scaffolds cultured in tenogenic but not in basal media for 21 days. The presence of IGF-1 increased osteogenic and chondrogenic differentiation of BMSCs, whereas no difference was observed for tenogenic differentiation. In conclusion, a 3-layer collagen sponge was successfully fabricated with distinct but integrated layers; the different collagen composition of the non-functionalized 3-layer sponge was able to regulate BMSC differentiation in a localized manner within the scaffold. The scaffold functionalization with IGF-1 accelerated chondrogenic and osteogenic BMSC differentiation. Overall, functionalization of the 3-layer scaffolds holds promising potential in enthesis regeneration.