Regional distribution of delamination strength in ascending thoracic aortic aneurysms.

Considering that the biomechanical factors underlying aortic dissection remain poorly understood as does the rationale for the anatomic localization of the dissection channel, we have attempted to determine the regional distribution of delamination/tensile strengths of ascending thoracic aortic aneurysm wall tissue. Whole aneurysms were taken from seventeen patients undergoing elective surgery and cut into a couple of specimens per quadrant and direction. The specimens were subjected to delamination- and tensile-testing, from which average peel tension (=delamination strength) and failure stress (=tensile strength) were assessed. Histology revealed no differences with region and direction in the roughness of the delaminated surfaces of the inner (intima with most of media) and outer layers (leftover media with adventitia). Compared to the right, the left lateral region exhibited significantly higher thickness and peel tension in both directions, but lower failure stress of the inner and outer layers longitudinally. Failure stress of the inner layers mostly but also of the outer layers was significantly higher circumferentially than longitudinally, with significantly higher values for the outer compared to the inner layers. Differing heterogeneity was evidenced in the delamination and tensile strength of aneurysmal tissue, with important implications for dissection propagation. Particularly, the increased resistance to propagation in the left lateral region helps address the question why part of the circumference, characteristically the right lateral wall, is involved by the dissection and the other part of the aortic wall remains intact. The deterioration of delamination strength with aging suggests the greater potential of aged individuals for dissection propagation.

Effect of Aneurysm and Bicuspid Aortic Valve on Layer-Specific Ascending Aorta Mechanics.

BACKGROUND: Previous studies have not examined the participation of intimal, medial, and adventitial layers in providing mechanical strength to the ascending thoracic aortic aneurysm (ATAA) wall compared with the nonaneurysmal aorta. In this study we compared the mechanical properties of intact wall and its layers among ATAAs and nonaneurysmal aortas, with explicit consideration of the effects of valve morphology; that is, bicuspid aortic valve (BAV) versus tricuspid aortic valve (TAV), and aortic quadrant. METHODS: Whole ATAAs were taken from patients undergoing elective repair and nonaneurysmal aortas from age-matched autopsy subjects. These were cut into 2 circumferential and longitudinal tissue strips for the intact wall and its layers per quadrant, permitting examination of the aortic wall as a multilayered structure. Tissue underwent tensile testing for determination of failure properties. RESULTS: Intact wall and layer-specific failure stretches (ie, extensibilities) were significantly greater in nonaneurysmal and BAV-ATAA than in TAV-ATAA, unaccounted for by elastin/collagen content changes. Intact wall failure stress (ie, strength) was significantly greater in BAV-ATAA than in TAV-ATAA, in analogy with medial failure stress. Failure stress and stretch associated negatively with age in most subject groups, layers, and intact wall, but failure stretch correlated positively with residual stretch (ie, structural bonds between layers). CONCLUSIONS: No mechanical vulnerability of BAV-ATAA was found, corroborating current conservative guidelines regarding the management of bicuspid aortopathy. Weakening and added vulnerability was found in patients with valvular deficiency, aortic root aneurysm, hypertension, and hyperlipidemia. Aging led to increased susceptibility to dissection initiation or full rupture, or both, in both patient classes.

Effects of aneurysm on the mechanical properties and histologic structure of aortic sinuses.

BACKGROUND: Aortic root aneurysms are relatively uncommon but their rupture is a detrimental event with acute hemodynamic compromise and high mortality, and there are few available data on their mechanical properties, although aneurysm rupture occurs when hemodynamic stresses exceed wall strength. This study aimed to fill this gap by examining the effect of aneurysm on the mechanical and structural properties of aortic sinuses. METHODS: Sinus tissue was procured from 16 aneurysmal patients during surgical repair and from 18 age-matched nonaneurysmal autopsy subjects, and grouped by age (young versus old), region (left versus right versus noncoronary), and direction (circumferential versus longitudinal). The tissue was submitted to histologic evaluation of elastin/collagen contents and to mechanical testing beyond rupture for the determination of failure properties and material characterization by the Fung-type model. RESULTS: Contrasting the direction-dependent (anisotropic) material constants and failure properties, and the primarily circumferential reinforcement of elastin/collagen fibers in healthy sinuses, near-similar (isotropic) properties and arbitrarily aligned fibers were found in the aneurysmal right and left coronary sinuses, together with less anisotropic properties in the aneurysmal noncoronary sinus. Variations between aneurysmal and healthy sinuses were comparable in young and old subjects. The former displayed significantly higher failure stress, failure stretch, and peak elastic modulus, justified by their increased elastin/collagen contents. CONCLUSIONS: We submit evidence of more isotropic histomechanical properties in the aneurysmal sinuses that seem consistent with the more axisymmetric stresses exerted on them owing to their more spherical shape, compared with the nondilated healthy sinuses that presented marked anisotropic properties.

Biomechanical properties and histological structure of sinus of Valsalva aneurysms in relation to age and region.

Information on the biomechanical properties of aortic root aneurysms that would facilitate our understanding of their rupture modes is currently unavailable. In this study, whole-thickness wall specimens from aortic root aneurysms were studied in vitro so as to compare the biomechanical properties with gross histomorphology and composition, in relation to age, region, and direction. The stress-strain relationship was determined under uniaxial loading conditions and characterized by the Fung-type material model in terms of optimized material constants; failure properties were recorded. The connective tissue contents of the basic scleroproteins were also determined through computerized histology. Aging had a deleterious influence on the tensile strength of the aneurysmal sinus tissue, causing also stiffening and reduced extensibility that was consistent with the deficient elastin and collagen contents. Direction-dependent differences were demonstrated in the noncoronary sinus, with the circumferential being stiffer and stronger than the longitudinal direction, justified by the preferred collagen reinforcement along that direction there. In the left and right coronary sinus, the material constants and failure properties were essentially the same in the two directions, justified by the arbitrary orientation of medial (collagen and elastin fibers, and cellular) components relative to the circumferential-longitudinal directions. The material characterization results afforded, and the regional and age-related differences in the strength of the sinus wall, i.e. in its capacity to withstand hemodynamic stresses, are hoped to provide novel insight into the pathophysiological mechanisms responsible for the highest incidence of ruptured aortic root aneurysms in the right coronary and noncoronary sinus.

Effect of layer heterogeneity on the biomechanical properties of ascending thoracic aortic aneurysms.

This study addressed layer-specific differences in the biomechanical response of ascending aortic aneusysms, obtained from patients during graft replacement. Tensile tests were conducted on pairs of (orthogonally directed) intimal, medial, and adventitial strips from the anterior, posterior, and two lateral quadrants. The experimental data were reduced by the Fung-type model, affording appropriate characterization of the material properties. Testing of individual layers beyond rupture disclosed their failure properties, namely their capacity to bear varying deformation and stress levels. Material parameters [Formula: see text] and [Formula: see text], specifying circumferential and longitudinal stiffness, received the highest values in the adventitia or intima and the smallest in the media, with [Formula: see text] > [Formula: see text] in every layer but the intima. Similar extensibility at failure was found among layers, whereas the adventitia was the strongest of all. Circumferentially and longitudinally directed strips from each layer did not show uniform material parameters and failure properties among regions, but most differences did not reach significance. Medial and adventitial but not intimal layers were stronger circumferentially than longitudinally. This is the first study to place emphasis on the biomechanical properties of the distinct layers of human aneurysmal aorta that may be expected to shed light into the mechanisms promoting aneurysm dissection and rupture.

Time course of flow-induced adaptation of carotid artery biomechanical properties, structure and zero-stress state in the arteriovenous shunt.

Numerous studies have provided evidence of diameter adaptation secondary to flow-overload, but with ambiguous findings vis à vis other morphological parameters and information on the biomechanical aspects of arterial adaptation is rather incomplete. We examined the time course of large-artery biomechanical adaptation elicited by long-term flow-overload in a porcine shunt model between the carotid artery and ipsilateral jugular vein. Post-shunting, the proximal artery flow was doubled and retained so until euthanasia (up to three months post-operatively), without pressure change. This hemodynamic stimulus induced lumen diameter enlargement, accommodated by elastin fragmentation and connective tissue accumulation, as witnessed by optical and confocal microscopy. Heterogeneous mass growth of the adventitia was observed at the expense of the media, associated with declining residual strains and opening angle at three months. The in vitro elastic properties of shunted arteries determined by inflation/extension testing were also modified, with the thickness-pressure curves shifted to larger thicknesses and the diameter-pressure curves shifted to larger diameters at physiologic pressures, resulting in normalization of intramural and shear stresses within fifteen and thirty days, respectively. We infer that the biomechanical adaptation in moderate flow-overload leads to normalization of intimal shear, without, however, restoring compliance and distensibility at mean in vivo pressure to control levels.

Biomechanical response of ascending thoracic aortic aneurysms: association with structural remodelling.

Ascending thoracic aortic aneurysms (ATAA) were resected from patients during graft replacement and non-aneurysmal vessels during autopsy. Tissues were histomechanically tested according to region and orientation, and the experimental recordings reduced with a Fung-type strain--energy function, affording faithful biomechanical characterisation of the vessel response. The material and rupture properties disclosed that ATAA and non-aneurysmal aorta were stiffer and stronger circumferentially, accounted by preferential collagen reinforcement. The deviation of microstructure in the right lateral region, with a longitudinal extracellular matrix and smooth muscle element sub-intimally, reflects the regional differences in material properties identified. ATAA had no effect on strength, but caused stiffening and extensibility reduction, corroborating our histological observation of deficient elastin but not collagen content. Our findings may serve as input data for the implementation of finite element models, to be used as improved surgical intervention criteria, and may further our understanding of the pathophysiology of ATAA and aortic dissection.

Differential histomechanical response of carotid artery in relation to species and region: mathematical description accounting for elastin and collagen anisotropy.

The selection of a mathematical descriptor for the passive arterial mechanical behavior has been long debated in the literature and customarily constrained by lack of pertinent data on the underlying microstructure. Our objective was to analyze the response of carotid artery subjected to inflation/extension with phenomenological and microstructure-based candidate strain-energy functions (SEFs), according to species (rabbit vs. pig) and region (proximal vs. distal). Histological variations among segments were examined, aiming to explicitly relate them with the differential material response. The Fung-type model could not capture the biphasic response alone. Combining a neo-Hookean with a two-fiber family term alleviated this restraint, but force data were poorly captured, while consideration of low-stress anisotropy via a quadratic term allowed improved simulation of both pressure and force data. The best fitting was achieved with the quadratic and Fung-type or four-fiber family SEF. The latter simulated more closely than the two-fiber family the high-stress response, being structurally justified for all artery types, whereas the quadratic term was justified for transitional and muscular arteries exhibiting notable elastin anisotropy. Diagonally arranged fibers were associated with pericellular medial collagen, and circumferentially and longitudinally arranged fibers with medial and adventitial collagen bundles, evidenced by the significant correlations of SEF parameters with quantitative histology.

Local hemodynamics and intimal hyperplasia at the venous side of a porcine arteriovenous shunt.

Venous anastomotic intimal hyperplasia (IH) observed in the arteriovenous shunt (AVS) has been associated with disturbed hemodynamics. This study aims to correlate hemodynamics with wall histology and wall mechanics by examining the flow field in AVS with computational fluid dynamics using experimental data taken from in vivo experiments. Input data to the computational model were obtained in vivo one month after AVS creation; adjacent vessels were submitted to histological and mechanical examination. The 3-D shunt geometry was determined using biplane angiography. Ultrasound measurements of flow rates were performed with perivascular flow probes and pressures were recorded through intravascular catheters. These data were considered as boundary conditions for calculation of the unsteady flow field. Numerical findings are suggestive of strong Dean vortices toward both vein flow exits, verified by color Doppler. The high wall shear stresses (WSSs) and their gradients appear to be related to areas of IH and vessel wall stiffening, as evidenced in preliminary histological and mechanical studies of the venous wall. Additionally, suture line hyperplasia seems to be aggravated by the high WSS gradients noted at the transition line from graft to vein.

Biomechanical, morphological and zero-stress state characterization of jugular vein remodeling in arteriovenous fistulas for hemodialysis.

While the role of hemodynamic variables on the development of intimal hyperplasia in arteriovenous fistulas for hemodialysis has been examined, less is known about the intramural biomechanical factors. In this study, arteriovenous fistulas were created by implantation of e-PTFE grafts between carotid artery and jugular vein in healthy pigs. In vivo recordings exhibited a three-fold pressure and flow elevation in grafted veins after fistula creation, remaining so until sacrifice. The chief morphological observation in grafted vessels was wall thickening at two weeks, serving to restore intramural stresses to homeostatic levels, and a less marked internal diameter enlargement, gradually normalizing intimal shear after four weeks. The residual strains and opening angle, specifying the zero-stress configuration, increased with differences reaching significance at twelve weeks. Association with histomorphological findings on intima, media and adventitia growth disclosed a correlation between intimal hyperplasia and opening angle increase. Elastin and cellular contents diminished opposite to collagen content, most differences occurring within the first four weeks after grafting. Inflation/extension testing showed that post-fistula the vein wall became progressively thicker and stiffer, lacking restoration of compliance to baseline levels. The present data may further our understanding of the dynamics of venous biomechanical remodeling under pressure and flow-overload conditions.

Ascending thoracic aortic aneurysms are associated with compositional remodeling and vessel stiffening but not weakening in age-matched subjects.

OBJECTIVE: We sought to examine in age-matched subjects the biomechanical and compositional remodeling associated with ascending thoracic aortic aneurysms according to region and direction. METHODS: Whole, fresh, degenerative ascending thoracic aortic aneurysms were taken from 26 patients (age, 69 +/- 2 years; maximum aortic diameter, 5.9 +/- 0.3 cm) during elective surgical intervention, and 15 nonaneurysmal ascending thoracic aortas were obtained during autopsies (age, 66 +/- 3 years; maximum aortic diameter, 3.3 +/- 0.2 cm). These were cut into anterior, right lateral, posterior, and left lateral regions, and circumferentially and longitudinally oriented specimens were prepared. The aortic specimens were submitted to histomorphometric and biomechanical studies, including measurement of failure strain (ie, extensibility), failure stress (ie, strength), and peak elastic modulus (ie, stiffness). RESULTS: Wall elastin, but not collagen content, decreased in aneurysmal specimens, displaying lower wall thickness and failure strain, higher peak elastic modulus, and equal failure stress than control specimens in the majority of regions and directions. Similar differences were noted in pooled data from all regions. Regional variations in mechanical parameters were mostly found in longitudinally oriented tissue. Circumferential specimens showed higher failure stress and peak elastic modulus but equal failure strain than longitudinal specimens. CONCLUSIONS: Our findings contradict previous studies on ascending thoracic and abdominal aortic aneurysms, suggesting that the former might not cause weakening but rather only stiffening and reduction in tissue extensibility and elastin content. Marked heterogeneity was evident in healthy and aneurysmal aortas. The present data offer insight into the pathogenesis of aneurysm dissection. Information on directional and regional variations is pertinent because dissections develop circumferentially and bulging preferentially occurs in the anterior region.

Regional and directional variations in the mechanical properties of ascending thoracic aortic aneurysms.

This study aimed to assess regional and directional differences in the mechanical properties of ascending thoracic aortic aneurysms (ATAA). Whole fresh ATAA were taken from twelve patients, undergoing elective surgical repair, and cut into tissue specimens. These were divided into groups according to direction and region, and subjected to uniaxial testing beyond rupture. In the majority of tests, the inner layers of the aortic wall ruptured first; failure stress (measure of tissue strength) and peak elastic modulus (measure of tissue stiffness) were significantly higher circumferentially in all regions. Marked heterogeneity was evident in the mechanical properties of ATAA, with the anterior region longitudinally being the weakest and least stiff of all regions. No correlation was found between failure stress and ATAA diameter or patient age. Failure stress showed inverse correlations with wall thickness and direct correlations with peak elastic modulus. The current information, relating to regional and directional differences, may provide a better understanding of the mechanism responsible for the development of circumferential tears of the inner aortic wall layers in ATAA dissections.