Tendon Differentiation on Decellularized Extracellular Matrix Under Cyclic Loading

In Vitro Cellular Strain Models of Tendon Biology and Tenogenic Differentiation

Research has shown that the surrounding biomechanical environment plays a significant role in the development, differentiation, repair, and degradation of tendon, but the interactions between tendon cells and the forces they experience are complex. In vitro mechanical stimulation models attempt to understand the effects of mechanical load on tendon and connective tissue progenitor cells. This article reviews multiple mechanical stimulation models used to study tendon mechanobiology and provides an overview of the current progress in modelling the complex native biomechanical environment of tendon. Though great strides have been made in advancing the understanding of the role of mechanical stimulation in tendon development, damage, and repair, there exists no ideal in vitro model. Further comparative studies and careful consideration of loading parameters, cell populations, and biochemical additives may further offer new insight into an ideal model for the support of tendon regeneration studies.

A 3D Dynamic In Vitro Model of Inflammatory Tendon Disease

Three-dimensional (3D) cell cultures combining multipotent mesenchymal stromal cells (MSC), tendon extracellular matrix scaffolds, and mechanical stimulation by a bioreactor have been used to induce tenogenic differentiation in vitro. Yet, these conditions alone do not mimic the environment of acute inflammatory tendon disease adequately, thus the results of such studies are not representatives for tendon regeneration after acute injury. In this chapter, we describe two different approaches to introduce inflammatory stimuli, comprising co-culture with leukocytes and supplementation with the cytokines IL-1 β and TNF-α. The presented in vitro model of inflammatory tendon disease could be used to study musculoskeletal pathophysiology and regeneration in more depth.