Biomechanics of regenerated esophageal tissue following the implantation of a tissue engineered CellspanTM Esophageal Implant

Abstract

The esophagus is a tubular organ with a multi-laminated tissue structure that functions to transport nutrition from the oral cavity to the stomach. Several diseases of the esophagus including congenital disorders require complete surgical esophagectomy. Ideally, segmental removal of the diseased/damaged tissue would spare the unaffected tissue and preserve organ function. To this end, a novel tissue engineered implant, the CellspanTM Esophageal Implant (CEI) was used to repair the esophagus following segmental resection of the thoracic esophagus in a porcine model. The current study investigated the mechanical strength and the associated tissue architecture of the CEI-stimulated tissue. The CEI bridged the proximal and distal native esophageal ends to restore the conduit by stimulating a regeneration process that progressed from a fibrovascular scar at 30-days to a fully epithelialized lumen at 90-days, followed by submucosal regeneration and regeneration of a ‘laminated’ adventitia with smooth muscle development in the 365-day cohort. The mechanical strength of the newly developed tissue as well as the flanking native tissue were assessed using a probe-burst pressure test (ASTM D6797-15). The burst pressures at all three time points were comparable to the native tissue flanking the implant. In addition, the overall pressure required to burst through both the native and regenerated tissues increased with increasing time post-implantation.