In vivo and in vitro mechanical properties of the sheep thoracic aorta in the perinatal period and adulthood

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In vivo and in vitro mechanical properties of the sheep thoracic aorta in the perinatal period and adulthood

Sarah M. Wells¹^,⁴^,⁶, B. Lowell Langille²^,³^,⁵, and S. Lee Adamson³^,⁶

¹ Departments of Metallurgy and Materials Science, ² Laboratory Medicine and Pathobiology, and ³ Obstetrics and Gynecology, and ⁴ Centre for Biomaterials, University of Toronto, ⁵ The Toronto Hospital Research Institute, and ⁶ Samuel Lunenfeld Research Institute, Mount Sinai Hospital, Toronto, Ontario, Canada M5G 1X5

The mammalian aorta undergoes rapid remodeling during the perinatal period and more gradual remodeling during subsequent development,but the implications of this remodeling for arterial mechanicsare poorly understood. In this study in vivo and in vitro techniqueswere used to determine the static and viscoelastic propertiesof the thoracic aortas of 119-day-gestation fetal sheep (fullterm = 145 days), 21-day-old lambs, and adult sheep at controldistending pressures and after 70% increases or 30% decreasesin pressure. In the weeks surrounding birth, aortic wall tissuebecame substantially stiffer (static elastic modulus in vitroincreased by 28%, and pressure wave velocity in vivo increasedby 61%) but less viscous (pressure wave attenuation in vivo decreasedby 46%, and viscoelastic phase angle in vitro decreased by 15%),whereas the wall thickness-to-radius ratio was unchanged. By contrast,modest changes in tissue viscoelasticity from neonatal to adultlife were accompanied by a halving of the wall thickness-to-radiusratio from 0.19 ± 0.01 to 0.10 ± 0.01. The relative thinning ofthe vessel wall, combined with a doubling of blood pressure afterbirth, resulted in a 265% increase in aortic wall tensile stressover the period of study. We concluded that rapid remodeling inthe perinatal period primarily alters the viscoelastic propertiesof aortic wall tissues, whereas more gradual postnatal remodelinglargely affects vessel geometry.

elasticity; wave propagation; development

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