Mechanobiology in Epithelial
3D Tissue Constructs






The common goal of all projects is to elucidate fundamental principles governing epithelial tissue mechanobiology and their relevance for tissue function and dysfunction. The projects are inspired by pressing research questions in the field of life sciences (denoted as hypotheses in the respective project descriptions). Each project is co-supervised by an interdisciplinary team consisting of a lead supervisor, a cross-disciplinary co-supervisor and, in some instances, a junior supervisor.

PROJECT A1
Mechanobiology of embryoid bodies
PROJECT A2
Mechanobiological regulation of breast epithelium organization and cell invasion
PROJECT A3
Mechanobiology of adhesion during implantation and early placentation
PROJECT A4
Modeling the 3D shaping of epithelial tissue: The effect of the mechanical microenvironment
PROJECT B1
3D mapping of epidermal tissue mechanics during growth and upon wounding
PROJECT B2
Consequences of disease-causing cytoskeletal mutations on epidermal tissue stability
PROJECT B3
Mechanostimulation of an innervated 3D skin model
PROJECT C1
Regulation of the epithelial-endothelial signaling interface by shear stress and substrate stiffness
PROJECT C2
Consequences of disease-causing cytoskeletal mutations on epidermal tissue stability
PROJECT C3
Guiding respiratory epithelium towards directed ciliary function
PROJECT D1
Natural and synthetic hybrid hydrogels to study the effect of mechanical anisotropy on cell behavior and guidance
PROJECT D2
Mechanobiological challenges related to hydrogel-based bioprinting technology for manufacturing novel 3D cell culture models
PROJECT D3
Magnetic micromanipulators for probing local rheological properties of scaffolds and vital 3D tissue constructs