An advanced cone-and-plate reactor for the in vitro-application of shear stress on adherent cells.

Endothelial cells (ECs) are permanently exposed to the blood flow and the resulting shear stress, its magnitude varying with the EC site in the blood stream. Along with other mechanical stimuli like vesselwall stretching or hydrostatic blood pressure, this shear stress modulates the endothelial cell function, morphology and gene expression. Here, we describe our improved cone-and-plate reactor that applies up to 10 dyn/cm(2) uniform wall shear stress on a defined, ring-shaped region on a culture dish. At the same time, a hydrostatic pressure of up to 195 mmHg can be applied by increasing the atmospheric pressure in the incubator box. Gas composition can be controlled additionally, used for maintaining CO2-homeostasis or inducing hypoxic conditions. For better comparability, six cone-and-plate systems can be used at the same time at different rotational velocities. The effects on cell morphology, cytoskeleton and cell alignment can be monitored during application using a laser scanning microscope. Flow conditions have been studied and a sufficient area of uniform wall shear stress could be shown. To exceed 10 dyn/cm(2), we suggest an increase in medium viscosity.