Ferrari, Dario; Sengupta, Arunima; Heo, Lyong; Pethö, Laszlo; Michler, Johann; Geiser, Thomas; de Jesus Perez, Vinicio A; Kuebler, Wolfgang M; Zeinali, Soheila; Guenat, Olivier T (2023). Effects of biomechanical and biochemical stimuli on angio- and vasculogenesis in a complex microvasculature-on-chip. iScience, 26(3), p. 106198. Elsevier 10.1016/j.isci.2023.106198
|
Text
1-s2.0-S2589004223002754-main.pdf - Published Version Available under License Creative Commons: Attribution (CC-BY). Download (10MB) | Preview |
The endothelium of blood vessels is a vital organ that reacts differently to subtle changes in stiffness and mechanical forces exerted on its environment (extracellular matrix (ECM)). Upon alteration of these biomechanical cues, endothelial cells initiate signaling pathways that govern vascular remodeling. The emerging organs-on-chip technologies allow the mimicking of complex microvasculature networks, identifying the combined or singular effects of these biomechanical or biochemical stimuli. Here, we present a microvasculature-on-chip model to investigate the singular effect of ECM stiffness and mechanical cyclic stretch on vascular development. Following two different approaches for vascular growth, the effect of ECM stiffness on sprouting angiogenesis and the effect of cyclic stretch on endothelial vasculogenesis are studied. Our results indicate that ECM hydrogel stiffness controls the size of the patterned vasculature and the density of sprouting angiogenesis. RNA sequencing shows that the cellular response to stretching is characterized by the upregulation of certain genes such as ANGPTL4+5, PDE1A, and PLEC.