Abstract
The enthesis is a tissue interface between tendon and bone, essential for adequate force transmission and composed by four distinct zones, namely tendon, fibrocartilage, mineralized fibrocartilage and bone. Given the avascularity of the tendon and the gradual change in tissue architecture and cell phenotype, the enthesis original tissue is often not re-established after chronic injuries, resulting in scar formation. Conservative treatments and surgical approaches are still far from a functional regeneration, whilst tissue engineering based scaffolds have recently showed great potential. In this work, we hypothesised that collagen-based scaffolds that mimic the basic architecture of the enthesis, will be able to spatially direct stem cell differentiation, providing an in vitro platform to study enthesis regeneration.
A three-layer sponge composed of a tendon-like layer (collagen type I), a fibrocartilage-like layer (collagen type II) and a bone-like layer (collagen type I and hydroxyapatite) was fabricated by an iterative layering freeze-drying technique. Scaffold pore size and structural continuity at the interfaces were assessed by SEM and μ-CT analysis. Bone-marrow derived stem cells (BMSCs) were seeded on the scaffold and cultured in basal and differentiation media (chondrogenic, tenogenic and osteogenic). At day 7 and 21 the scaffolds were stained with Alizarin Red and Alcian Blue; alkaline phosphatase activity (ALP) and calcium and glycosaminoglycans (GAGs) were quantified in order to evaluate BMSC differentiation towards osteogenic and chondrogenic lineage. The presence of collagen I, III, tenascin and decorin in the scaffolds was evaluated by immunofluorescence staining in order to evaluate tenogenic differentiation of BMSCs.
Scaffolds with three distinct but interconnected layers of collagen type I, collagen type II and collagen type I + hydroxyapatite were fabricated, with pore sizes in the range of 100–200 μm. Increased ALP and calcium levels were detected in a localised manner within the bone-like layer when scaffolds were cultured in basal medium (p<0.025 vs the other 2 layers). Similarly, proteoglycans were detected specifically in the fibrocartilage-like layer when scaffolds were cultured in the chondrogenic differentiation medium (p<0.03 vs the other 2 layers). Increased expression of tenogenic markers was observed in the tendon-like layer of scaffolds cultured in tenogenic media (p<0.045 vs the other 2 layers).
In conclusion, the different collagen composition of each layer was able to spatially direct BMSC differentiation in a localized manner within the scaffold. Ongoing work is evaluating the synergistic effect between growth factor functionalized within the fibrocartilage and tendon-like layers for improved BMSC differentiation. Overall, these scaffolds hold promising potential in developing novel and more efficient strategy towards enthesis regeneration.
