Abstract
Abstract
Objectives
The enthesis is a specialised structure at the interface between bone and tendon with gradual integration to maintain functionality and integrity. In the process of fabricating an in-vitro model of this complex structure, this study aims to investigate growth and maturation of bone, tendon and BMSC spheroids followed by 3D mini-tissue production.
Methods
Cell spheroids Spheroids of differentiated rat osteoblasts (dRObs), rat tendon fibroblasts (RTFs) and bone marrow stem cells (BMSC) were generated by culturing in 96 well U bottom cell repellent plates. With dROb spheroids previously analysed [1], RTF spheroids were examined over a duration of up to 28 days at different seeding densities 1×104, 5×104, 1×105, 2×105 in different media conditions with and without FBS (N=3). Spheroid diameter was analysed by imageJ/Fiji; Cell proliferation and viability was assessed by trypan blue staining after dissociating with accutase + type II collagenase mix; necrotic core by H&E staining; and extracellular matrix by picro-sirius red (RTFs) staining to visualise collagen fibres under bright-field and polarised light microscope.
3D mini-tissue constructs
15 day old mineralised dROb spheroids (∼1.5mm diameter) were deposited in pillar array supports using a customised spheroid deposition system to allow 3D mini-tissue formation via fusion (N=3). Similarly BMSC and RTF spheroids were deposited after determining the seeding density that produced spheroid size equivalent to 15 day old dROb spheroids. Gentle removal of spheroids from supports was performed on day 2, 4 and 6 to assess spheroid fusion. Histological staining was performed to observe cellular arrangement and extracellular matrix.
Results
RTF spheroids diameter reduced over the course of 28 days regardless of the seeding density. A substantial decline in cell numbers over time was observed and suggests lack of cell proliferation due to tenogenic differentiation. Absence of a necrotic core in RTF spheroids, in all seeding densities, reveals their inherent capacity to maintain cell viability in avascular conditions. Picro-sirius red staining demonstrated the presence of collagen type I fibres predominantly in peripheral regions of spheroids maintaining its shape. Small amounts of collagen type III were also noticed. The dROb spheroids fused rapidly within 2 days resulting in the formation of a mini-tissue. 2×105 RTFs and 3×105 BMSCs produced spheroids of ∼1.5mm on day 3 and day 1 respectively. When these spheroids were deposited in pillar array supports, they did not undergo fusion even up to 6 days. This suggests inadequate aggregation of spheroids and insufficient ECM production at this early stage.
Conclusions
This study has demonstrated the ability of RTFs to produce necrotic core-free spheroids with collagen fibres maintaining their structural integrity. For mini-tissue formation, we predict a longer initial culture time of RTF and BMSC spheroids will allow increased cellular interaction and ECM production before deposition, and will facilitate spheroid fusion. These findings will be applied in producing heterogenous mini-tissues, serving as a 3D in-vitro enthesis model.
Declaration of Interest
(a) fully declare any financial or other potential conflict of interest