Nondestructive Measurement of Regenerated Esophageal Biaxial Mechanical Properties Utilizing Sonometry For Determination of Directional Esophageal Regeneration

Abstract

Esophageal diseases often necessitate resection of tissue. Current reconstruction options using autologous conduits such as stomach, colon, and small bowel have significant morbidity. Given these limitations in current therapy, we have developed a large animal model to regenerate short segments of esophageal tissue after circumferential full thickness resection. This is performed by implantation of an electrospun polyurethane tissue engineered graft which results in esophageal regrowth. These implantations have been performed both with cell based seeding the polymer scaffold and without with comparable regenerative results. It is possible that esophageal regeneration in this model has unequal contributions from either the proximal or distal esophagus. To determine preferential directionality of regeneration we aim to utilize biomechanical markers to suggest that there are unequal proximal and distal contributions to regenerated tissue. Given limited availability of regenerated tissue, use of a non‐destructive method to perform this testing would have significant utility. Through using our previously validated non‐destructive sonometric ex vivo method we aim to determine differences in mechanical behavior of the regenerated tissue in comparison to proximal and distal esophageal tissues. Using this method we are able to determine longitudinal and circumferential moduli and derive strain energy functions and parameters. Within this work we demonstrate that there are differences in mechanical behavior and that the regenerated tissue behaves more comparably to proximal esophageal tissue suggesting preferential regrowth and unequal contribution to regenerated tissue.This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.