Abstract
BackgroundTwo-dimensional (2D) echocardiography is one of the most feasible, noninvasive methods for assessing the aortic diameter and biomechanical changes. We studied possible interfaces between noninvasive biomechanical and speckle-tracking (ST) echocardiographic data from dilated aortas.MethodsAltogether, 44 patients with dilative pathology of ascending aorta (DPAA) were compared with subjects without ascending aortic dilation (diameter <40 mm). DPAA patients formed two groups based on diameter size: group 1, ≤45 mm diameter; group 2, >45 mm. Conventional and 2D-ST echocardiography were performed to evaluate peak longitudinal strain (LS), longitudinal (LD) and transverse (TD) displacement, and longitudinal velocity (VL). Aortic strain, distensibility, elastic modulus, stiffness index β of Valsalva sinuses and ascending aorta were also evaluated. SPSS version 20 was used for all analyses.ResultsAll linear diameters of the ascending aorta were increased in group 2 (>45 mm diameter) (p < 0.05). LD of the anterior aortic wall (p < 0.05) and TD of both aortic walls (p < 0.001) were least in group 2. VL of the posterior and anterior walls diminished in group 2 (p = 0.01). Aortic strain and distensibility were least (p = 0.028 and p = 0.001, respectively) and elastic modulus and stiffness index β values were greatest in group 2, although without statistical significance.ConclusionsAscending aortas of both DPAA groups had reduced elasticity and increased stiffness. The greatest changes in biomechanical parameters occurred in ascending aortas >45 mm. Longitudinal ascending aortic wall motion was mostly impaired in patients with aortas >45 mm (i.e., anterior aortic wall LD, VL of the posterior and anterior walls. TD of the posterior and anterior aortic walls was significantly lower in >45 mm aortic diameter patients. TD of 5.2 mm could predict aortic dilation >45 mm (area under the curve 0.76, p < 0.001, confidence interval 0.65–0.87; sensitivity 87%; specificity 63%). Greater aortic dilation is associated with reduced aortic stiffness parameters and increased elastic modulus and stiffness index β. Lower LD and LS were associated with less aortic strain and distensibility. There were no significant differences in 2D-ST echocardiographic or stiffness parameters between patients with tricuspid or bicuspid aortic valves.
Highlights
Two-dimensional (2D) echocardiography is one of the most feasible, noninvasive methods for assessing the aortic diameter and biomechanical changes
We evaluated the peak longitudinal strain (LS), which is considered the change in segment length/resting segment length—i.e., deformation of an object relative to its original length; longitudinal (LD) and transverse (TD) displacements, defined as a change in the position of an object; and longitudinal velocity (VL), displacement of an object per time unit—of the Valsalva sinuses and the ascending part of the aorta (Fig. 1)
Systolic blood pressure was highest in group 2, and diastolic blood pressure was highest in the controls
Summary
Two-dimensional (2D) echocardiography is one of the most feasible, noninvasive methods for assessing the aortic diameter and biomechanical changes. Aortic dilation is the most frequent pathology of the ascending aorta and a well-known risk factor for dissection. Because of the increased risk of aortic dissection, surgical repair is recommended for patients with an ascending aorta aneurysm [1]. Two-dimensional (2D) echocardiography is one of the most feasible and the oldest method for diagnosing this pathology. It can be used for diameter assessment and for noninvasive measurement of biomechanical changes in the aorta
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