Design and hydrodynamic evaluation of a novel pulsatile bioreactor for biologically active heart valves.

Biologically active heart valves (tissue engineered and recellularized tissue-derived heart valves) have the potential to offer enhanced function when compared to current replacement value therapies since they can possibly remodel, and grow to meet the needs of the patient, and not require chronic medication. However, this technology is still in its infancy and many fundamental questions remain as to how these valves will function in vivo. It has been shown that exposing biologically active tissue constructs to pulsatile pressures and flows during in vitro culture produces enhanced extracellular matrix protein expression and cellularity, although the ideal hydrodynamic conditioning regime is as yet unknown.

A novel bioreactor for the dynamic flexural stimulation of tissue engineered heart valve biomaterials.

Dynamic flexure is a major mode of deformation in the native heart valve cusp, and may effect the mechanical and biological development of tissue engineered heart valves (TEHV). To explore this hypothesis, a novel bioreactor was developed to study the effect of dynamic flexural stimulation on TEHV biomaterials. It was implemented in a study to compare the effect of uni-directional cyclic flexure on the effective stiffness of two candidate TEHV scaffolds: a non-woven mesh of polyglycolic acid (PGA) fibers, and a non-woven mesh of PGA and poly L-lactic acid (PLLA) fibers, both coated with poly 4-hydroxybutyrate (P4HB).