Purpose: Acute type A aortic dissection (AD) is a catastrophic event associated with high mortality. Biomechanics can provide an understanding of the forces that lead the initial intimal tear to propagate, resulting in aortic dissection. We previously studied the material properties of normal human aortic roots. In this study, our objective was to determine the regional and directional delamination properties of healthy human ascending aorta (AscAo) and sinotubular junction (STJ).
Results: From 19 healthy donor hearts, total 107 samples from the AscAo and STJ were collected and tested along the circumferential and longitudinal directions. Specimens were subjected to uniaxial peeling testing with a manually created tear in the medial layer. The lateral AscAo subregion (greater curvature) had significantly lower delamination strength and dissection energy than anterior, medial, and posterior subregions in the longitudinal direction. Regionally, the delamination strength at AscAo was significantly lower than at STJ overall (p = 0.02) and in circumferential direction (p = 0.02) only. Directionally, the delamination strength at AscAo overall and in the anterior AscAo was significant lower in circumferential direction than longitudinal direction. Dissection energy demonstrated similar regional and directional trend as delamination strength. In addition, both dissection energy and delamination strength were correlated positively with thickness and negatively with age in the AscAo. In addition, the dissection energy was negatively related to stiffness at physiologic mean blood pressure.
Conclusions: The greater curvature of the AscAo had the lowest delamination strength and dissection energy suggesting that region was most vulnerable to dissection propagation distally. Increased thickness of AscAo would be protective of dissection propagation while propagation would be more likely with increased AscAo stiffness.
Keywords: Aortic dissection; Ascending aorta; Biomechanics; Delamination.
Published by Elsevier Ltd.