Biomechanical modelling used to simulate functional performance of skeleton and muscle systems in vertebrates. For studying how tissues respond to mechanical loading during movement, we apply finite element modelling. For studying how muscles interact with skeletal elements, and how they make them

The Vectra® Polaris™ Automated Quantitative Pathology Imaging System integrates both multispectral imaging and automated slide scanning to better visualize, analyze, quantify, and phenotype immune cells in situ in FFPE tissue sections and TMAs.

The scope of our research ranges from the study of flow and transport processes in blood and biological fluids in the cardiovascular system and artificial organs to biomechanical aspects of the cardiovascular and the skeleto-muscular system and medical devices. All research tracks explored by our

Functional cardiomyocytes can be efficiently derived from human pluripotent stem cells, which collectively include embryonic and induced pluripotent stem cells (iPSC). Specific affected biological pathways involved in disease can be functionally studied in differentiated cells at a single patient