AI Article Synopsis
- The study investigates how temperature affects the mechanical behavior of two types of human arteries, the carotid artery and the aorta, which is important for understanding artery functions and surgical practices.
- Experimental data were collected by measuring the pressure and diameter of arteries at varying temperatures (17, 27, 37, and 42 degrees C) to assess their mechanical properties.
- Results showed that arteries become more compliant with higher temperatures, and their expansion behavior depends significantly on internal pressure, with different reactions observed at low versus higher pressures.
Article Abstract
Introduction And Objectives: The thermomechanical behavior of human arteries is still not well characterized despite its importance for understanding arterial physiology, and for evaluating and improving surgical procedures. The aim of this study was to provide, for the first time, experimental data illustrating how the mechanical responses of two types of human artery -the carotid artery and the aorta- are affected by changes in temperature.
Methods: The mechanical properties of the arteries were derived in vitro from internal pressure-external diameter curves measured at four different temperatures (i.e., 17, 27, 37 and 42 degree C). Coefficients of expansion and stiffness were obtained by thermomechanical analysis. The condition of the arterial wall was determined histologically.
Results: The aorta and the carotid artery became slightly more compliant as the temperature increased. In both vessels, the coefficient of expansion depended critically on internal pressure. At low pressures, the coefficient of expansion was negative (i.e., the vessel contracted when heated), whereas close to a specific threshold pressure, which is different for each type of artery, the coefficient became positive.
Conclusions: The mechanical behavior of arteries is affected by the combination of internal pressure and temperature. Consequently, the effect of this combination should be taken into account in clinical situations involving a change in temperature. Moreover, the strength of the effect depends on the type of artery under study. As a result, more detailed experimental data focusing on vessels of clinical interest are required.
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