Dar Weiss1, Aaron S Long1, George Tellides2,3, Stéphane Avril4, Jay D Humphrey1,3, Matthew R Bersi1,5. 1. Department of Biomedical Engineering (D.W., A.S.L., J.D.H., M.R.B.), Yale University, New Haven, CT. 2. Department of Surgery (G.T.), Yale University, New Haven, CT. 3. Vascular Biology and Therapeutics Program, Yale School of Medicine, New Haven, CT (G.T., J.D.H.). 4. Mines Saint-Etienne, University of Lyon, University Jean Monnet, INSERM, France (S.A.). 5. Department of Mechanical Engineering and Materials Science, Washington University in St. Louis, MO (M.R.B.).
Abstract
BACKGROUND: Thoracic aortopathy associates with extracellular matrix remodeling and altered biomechanical properties. We sought to quantify the natural history of thoracic aortopathy in a common mouse model and to correlate measures of wall remodeling such as aortic dilatation or localized mural defects with evolving microstructural composition and biomechanical properties of the wall. METHODS: We combined a high-resolution multimodality imaging approach (panoramic digital image correlation and optical coherence tomography) with histopathologic examinations and biaxial mechanical testing to correlate spatially, for the first time, macroscopic mural defects and medial degeneration within the ascending aorta with local changes in aortic wall composition and mechanical properties. RESULTS: Findings revealed strong correlations between local decreases in elastic energy storage and increases in circumferential material stiffness with increasing proximal aortic diameter and especially mural defect size. Mural defects tended to exhibit a pronounced biomechanical dysfunction that is driven by an altered organization of collagen and elastic fibers. CONCLUSIONS: While aneurysmal dilatation is often observed within particular segments of the aorta, dissection and rupture initiate as highly localized mechanical failures. We show that wall composition and material properties are compromised in regions of local mural defects, which further increases the dilatation and overall structural vulnerability of the wall. Identification of therapies focused on promoting robust collagen accumulation may protect the wall from these vulnerabilities and limit the incidence of dissection and rupture.
BACKGROUND: Thoracic aortopathy associates with extracellular matrix remodeling and altered biomechanical properties. We sought to quantify the natural history of thoracic aortopathy in a common mouse model and to correlate measures of wall remodeling such as aortic dilatation or localized mural defects with evolving microstructural composition and biomechanical properties of the wall. METHODS: We combined a high-resolution multimodality imaging approach (panoramic digital image correlation and optical coherence tomography) with histopathologic examinations and biaxial mechanical testing to correlate spatially, for the first time, macroscopic mural defects and medial degeneration within the ascending aorta with local changes in aortic wall composition and mechanical properties. RESULTS: Findings revealed strong correlations between local decreases in elastic energy storage and increases in circumferential material stiffness with increasing proximal aortic diameter and especially mural defect size. Mural defects tended to exhibit a pronounced biomechanical dysfunction that is driven by an altered organization of collagen and elastic fibers. CONCLUSIONS: While aneurysmal dilatation is often observed within particular segments of the aorta, dissection and rupture initiate as highly localized mechanical failures. We show that wall composition and material properties are compromised in regions of local mural defects, which further increases the dilatation and overall structural vulnerability of the wall. Identification of therapies focused on promoting robust collagen accumulation may protect the wall from these vulnerabilities and limit the incidence of dissection and rupture.
Authors: Loren F Hiratzka; George L Bakris; Joshua A Beckman; Robert M Bersin; Vincent F Carr; Donald E Casey; Kim A Eagle; Luke K Hermann; Eric M Isselbacher; Ella A Kazerooni; Nicholas T Kouchoukos; Bruce W Lytle; Dianna M Milewicz; David L Reich; Souvik Sen; Julie A Shinn; Lars G Svensson; David M Williams Journal: Circulation Date: 2010-03-16 Impact factor: 29.690
Authors: Linda A Pape; Mazen Awais; Elise M Woznicki; Toru Suzuki; Santi Trimarchi; Arturo Evangelista; Truls Myrmel; Magnus Larsen; Kevin M Harris; Kevin Greason; Marco Di Eusanio; Eduardo Bossone; Daniel G Montgomery; Kim A Eagle; Christoph A Nienaber; Eric M Isselbacher; Patrick O'Gara Journal: J Am Coll Cardiol Date: 2015-07-28 Impact factor: 24.094
Authors: Debra L Rateri; Frank M Davis; Anju Balakrishnan; Deborah A Howatt; Jessica J Moorleghen; William N O'Connor; Richard Charnigo; Lisa A Cassis; Alan Daugherty Journal: Am J Pathol Date: 2014-07-16 Impact factor: 4.307
Authors: Jay D Humphrey; David G Harrison; C Alberto Figueroa; Patrick Lacolley; Stéphane Laurent Journal: Circ Res Date: 2016-02-05 Impact factor: 17.367
Authors: Changshun He; Bo Jiang; Mo Wang; Pengwei Ren; Sae-Il Murtada; Alexander W Caulk; Guangxin Li; Lingfeng Qin; Roland Assi; Constantinos J Lovoulos; Martin A Schwartz; Jay D Humphrey; George Tellides Journal: JCI Insight Date: 2022-02-08