Micromachining of Polyurethane Membranes for Tissue Engineering Applications.

Engineered tissue barrier models offer alternatives in toxicology and disease research. To mimic barrier-tissue microenvironment, a porous membrane that can approach the stiffness of physiological basement membranes is required. While several biocompatible membranes with micrometer range thickness (10 μm) and a stiffness less than polystyrene (3 GPa) or polyethylene (PET, 2 GPa), have been developed, there has been little effort to optimize the process to enable rapid and reproducible pore production in these membranes.

A microfluidic method to measure bulging heights for bulge testing of polydimethylsiloxane (PDMS) and polyurethane (PU) elastomeric membranes.

Thin and flexible elastomeric membranes are frequently used in many microfluidic applications including microfluidic valves and organs-on-a-chip. The elastic properties of these membranes play an important role in the design of such microfluidic devices. Bulge testing, which is a common method to characterize the elastic behavior of these membranes, involves direct observation of the changes in the bulge height in response to a range of applied pressures.