posted on 2019-05-14, 00:00authored byAntonio D’Amore, Samuel K. Luketich, Richard Hoff, Sang-Ho Ye, William R. Wagner
After
more than 22 years of research challenges and innovation,
the heart valve tissue engineering paradigm still attracts attention
as an approach to overcome limitations which exist with clinically
utilized mechanical or bioprosthetic heart valves. Despite encouraging
results, delayed translation can be attributed to limited knowledge
on the concurrent mechanisms of biomaterial degradation in vivo, host
inflammatory response, cell recruitment, and de novo tissue elaboration.
This study aimed to reduce this gap by evaluating three alternative
levels at which lability could be incorporated into candidate polyurethane
materials electroprocessed into a valve scaffold. Specifically, polyester
and polycarbonate labile soft segment diols were reacted into thermoplastic
elastomeric polyurethane ureas that formed scaffolds where (1) a single
polyurethane containing both of the two diols in the polymer backbone
was synthesized and processed, (2) two polyurethanes were physically
blended, one with exclusively polycarbonate and one with exclusively
polyester diols, followed by processing of the blend, and (3) the
two polyurethane types were concurrently processed to form individual
fiber populations in a valve scaffold. The resulting valve scaffolds
were characterized in terms of their mechanics before and after exposure
to varying periods of pulsatile flow in an enzymatic (lipase) buffer
solution. The results showed that valve scaffolds made from the first
type of polymer and processing combination experienced more extensive
degradation. This approach, although demonstrated with polyurethane
scaffolds, can generally be translated to investigate biomaterial
approaches where labile elements are introduced at different structural
levels to alter degradation properties while largely preserving the
overall chemical composition and initial mechanical behavior.