Flow chambers have been implemented in stem cell research to apply controlled dilational (volume changing) and deviatoric (shape changing) mechanical cues to living cells. Studies implementing such chambers demonstrate that controlled delivery of mechanical cues correlates strongly to changes in stem cell shape, structure, and fate. A custom designed flow chamber, capable of delivering highly controlled stresses at the cellular scale, enables the study of flow-induced normal and shear stresses on cell behavior. Specifically, computational fluid dynamics (CFD) and multiphysics modeling (coupling of CFD with finite element models) allow for controlled delivery of mechanical cues via fluid flow and cell seeding protocols, concomitant to optical mapping of cell displacements due to mechanical load, and calculation of flow velocities, imbued stresses, and cellular strains within a given volume of interest. Akin to conducting a mechanical loading test on single cells and groups of cells, paired experimental and computational experiments using the custom-designed chamber enabled calculation of the flow field's effect on the cell(s) as well as the cells’ effect on the flow field, a critical step in predicting the local stress and strain fields at the cell-fluid interface within the chamber, during exposure to fluid flow. These stresses-strains experienced by stem cells demonstrate significant correlation to cell gene expression, and strongly suggest that stresses at the cell-fluid interface influence cell fate. The current study uses a parametric approach to define next steps to prospectively guide mechanically-modulated lineage commitment.Summary Statement
Introduction
Progenitor cells from the periosteal niche are of great clinical interest due to their remarkable regenerative capacity. Here we report on progenitor cells from arthritic patients whose femoral neck periosteum was resected over the course of hip replacement. This study aims to determine whether periosteum derived cells (PDCs) can be isolated from tissue resected in the normal course of hip arthroplasty. Further, it aims to determine how different isolation protocols affect PDC behavior (surface marker expression, proliferation, and differentiation). In addition, the study aims to characterise the populations of PDCs, isolated through either enzymatic digestion or migration, and their relative capacity to differentiate down multiple capacities; direct comparison with commercially available human marrow-derived stromal cells cultured under identical conditions will enable the placement of the PDC data in context of the current state of the field.Summary Statement
Introduction
