MACROMOLECULAR CROWDING AND MECHANICAL STIMULATION FOR TENOGENIC PHENOTYPE MAINTENANCE AND DIFFERENTIATION / TRANSDIFFERENTIATION

Cell-based tissue engineering strategies for tendon repair have limited clinical applicability due to delayed extracellular matrix (ECM) deposition and subsequent prolonged culture periods, which lead to tenogenic phenotypic drift. Deposition of ECM in vitro can be enhanced by macromolecular crowding (MMC), a biophysical phenomenon that governs the intra- and extra-cellular milieu of multicellular organisms, which has been described to accelerate ECM deposition in human tenocytes. A variety of cell sources have been studied for tendon repair including tenocytes, dermal fibroblasts (DFs) and mesenchymal stem cells (MSCs) and various biophysical, biochemical and biological tools have been used to mimic tendon microenvironment. Therefore, we propose to assess the combined effect of MMC and mechanical loading on different cell sources to determine their suitability for the in vitro fabrication of tendon-like tissue. The uniaxial strain induced differential cell orientation based on the differentiation state o...