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Patient-Specific Analysis of Ascending Thoracic Aortic Aneurysm with the Living Heart Human Model

Authors :
Andrew D. Wisneski
Giuseppe Maria Raffa
Giovanni Gentile
Salvatore Cutugno
Valentina Agnese
Salvatore Pasta
Michele Pilato
Julius M. Guccione
Cutugno S.
Agnese V.
Gentile G.
Raffa G.M.
Wisneski A.D.
Guccione J.M.
Pilato M.
Pasta S.
Source :
Bioengineering, Volume 8, Issue 11, Bioengineering, Vol 8, Iss 175, p 175 (2021)
Publication Year :
2021
Publisher :
MDPI AG, 2021.

Abstract

In ascending thoracic aortic aneurysms (ATAAs), aneurysm kinematics are driven by ventricular traction occurring every heartbeat, increasing the stress level of dilated aortic wall. Aortic elongation due to heart motion and aortic length are emerging as potential indicators of adverse events in ATAAs<br />however, simulation of ATAA that takes into account the cardiac mechanics is technically challenging. The objective of this study was to adapt the realistic Living Heart Human Model (LHHM) to the anatomy and physiology of a patient with ATAA to assess the role of cardiac motion on aortic wall stress distribution. Patient-specific segmentation and material parameter estimation were done using preoperative computed tomography angiography (CTA) and ex vivo biaxial testing of the harvested tissue collected during surgery. The lumped-parameter model of systemic circulation implemented in the LHHM was refined using clinical and echocardiographic data. The results showed that the longitudinal stress was highest in the major curvature of the aneurysm, with specific aortic quadrants having stress levels change from tensile to compressive in a transmural direction. This study revealed the key role of heart motion that stretches the aortic root and increases ATAA wall tension. The ATAA LHHM is a realistic cardiovascular platform where patient-specific information can be easily integrated to assess the aneurysm biomechanics and potentially support the clinical management of patients with ATAAs.

Details

ISSN :
23065354
Volume :
8
Database :
OpenAIRE
Journal :
Bioengineering
Accession number :
edsair.doi.dedup.....c2723ec78565f5c78d85bcd5b428cd47
Full Text :
https://doi.org/10.3390/bioengineering8110175