Abstract
Successful re-epithelialization of de-epithelialized tracheal scaffolds remains a challenge for tracheal graft success. Currently, the lack of understanding of the bioreactor hydrodynamic environment, and its relation to cell seeding outcomes, serve as major obstacles to obtaining viable tracheal grafts. In this work, we used computational fluid dynamics to (a) re-design the fluid delivery system of a trachea bioreactor to promote a spatially uniform hydrodynamic environment, and (b) improve the perfusion cell seeding protocol to promote homogeneous cell deposition. Lagrangian particle-tracking simulations showed that low rates of rotation provide more uniform circumferential and longitudinal patterns of cell deposition, while higher rates of rotation only improve circumferential uniformity but bias cell deposition proximally. Validation experiments with human bronchial epithelial cells confirm that the model accurately predicts cell deposition in low shear stress environments. We used the acquired knowledge from our particle tracking model, as a guide for long-term tracheal repopulation studies. Cell repopulation using conditions resulting in low wall shear stress enabled enhanced re-epithelialization of long segment tracheal grafts. While our work focuses on tracheal regeneration, lessons learned in this study, can be applied to culturing of any tissue engineered tubular scaffold.
Highlights
Successful re-epithelialization of de-epithelialized tracheal scaffolds remains a challenge for tracheal graft success
We hypothesized that in silico modelling of bioreactor modifications would allow for a clear understanding of their effect on the hydrodynamic environment within the construct, providing in silico guidance to accelerate the optimization of re-epithelialization protocols for tracheal scaffolds
We have found no previous work focused on predicting cell deposition patterns in tubular scaffolds such as the trachea
Summary
Successful re-epithelialization of de-epithelialized tracheal scaffolds remains a challenge for tracheal graft success. Computational Fluid Dynamics (CFD) has been used to quantify the flow velocity fields and shear stresses on tissue s caffolds[12,13,14,15] These studies, though useful in understanding the hydrodynamic environment of the scaffolds, fail to consider the effect of the bioreactor design and the flow delivery m echanism[16,17,18,19,20]. CFD, together with the Discrete Phase Model (DPM) was employed to predict the cell deposition patterns on a tubular scaffold inside our bioreactor. This particle tracking model was experimentally validated using human bronchial epithelial cells (BEAS-2B) cells in the trachea bioreactor. We used the acquired knowledge from our particle tracking model, as a guide for long-term tracheal repopulation studies
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