Rapid Prototypable Biomimetic Peristalsis Bioreactor Capable of Concurrent Shear and Multi-axial Strain

Peristalsis is a nuanced mechanical stimulus comprised of multi-axial strain (radial and axial strain) and shear stress. Forces associated with peristalsis regulate diverse biological functions including digestion, reproductive function, and urine dynamics. Given the central role peristalsis plays in physiology and pathophysiology, we were motivated to design a bioreactor capable of holistically mimicking peristalsis. We engineered a novel rotating screw-drive based design combined with a peristaltic pump, in order to deliver multiaxial strain and concurrent shear stress to a biocompatible polydimethylsiloxane (PDMS) membrane “wall”. Radial indentation and rotation of the screw drive against the wall demonstrated multi-axial strain evaluated via finite element modeling. Experimental measurements of strain using piezoelectric strain resistors were in close alignment of model-predicted values (15.9 ± 4.2% vs. 15.2% pr edicted). Modeling of shear stress on the ‘wall’ indicated a uniform velocity profile and a moderate shear stress of 0.4 Pa. Human mesenchymal stem cells (hMSCs) seeded on the PDMS ‘wall’ and stimulated with peristalsis demonstrated dramatic changes in actin filament alignment, proliferation , and nuclear morphology compared to static controls, perfusion or strain, indicating that hMSCs sensed and responded to peristalsis uniquely. Lastly, significant differences were observed in gene expression patterns of Calponin, Caldesmon, Smooth Muscle Actin, an...
Source: Cells Tissues Organs - Category: Cytology Source Type: research