Design of a modular bioreactor to incorporate both perfusion flow and hydrostatic compression for tissue engineering applications.

Physiological models have demonstrated that cells undergo a cyclic regimen of hydrostatic compression and fluid shear stress within the lacunar-canalicular porosity of bone. A new modular bioreactor was designed to incorporate both perfusion fluid flow and hydrostatic compression in an effort to more accurately simulate the mechanical loading and stress found in natural bone in vivo. The bioreactor design incorporated custom and off-the-shelf components to produce levels of mechanical stimuli relevant to the physiologic range, including hydrostatic compression exceeding 300 kPa and perfusion shear stress of 0.

Design and evaluation of a novel flow chamber for measuring cell adhesion to absorbable polymer films.

There is great interest in improving cellular attachment to synthetic materials, particularly for developing small diameter tissue-engineered vascular grafts. However, limited research has been conducted to evaluate the adhesion characteristics of different cell types to absorbable substrates. Tissue engineered vessels typically fail as a result of delamination of the endothelial cell layer when exposed to fluid or blood flow.