Effect of the hemodynamic overload on the arterial wall of the aortic bifurcation: development of a murin model of aneurysmatic structural fatigue

BACKGROUND: Experimental evidence indicates that altered patterns of vascular flow associated with bifurcations are involved in the development of aneurysmatic lesions. The effects of the hemodynamic overload on the arterial wall of the aortic bifurcation in murine models were studied. METHODS: Sixty Wistar rats were selected and assigned by simple random sampling into a control group and three experimental groups. The specimens were anesthetized. Under microscopic magnification an abdominal incision was performed and the aortic and iliac vessels were isolated from the infra-renal portion until the distal bifurcation. The modification of the geometry of the aortic bifurcation was accomplished by tunneling of the distal iliac artery into ilio-lumbar muscle in groups II and IV. Left nephrectomy and ligation of inferior right renal artery were completed to enhance the hemodynamic stress in groups III and IV. The models were maintained in conventional laboratory conditions with standard diet for the species and water ad libitum for groups I and II, and NaCl 0.9% for groups III and IV. After six months of follow up, the aortic bifurcation and iliac arteries were inspected and subsequently removed to its histopathological evaluation. One specimen from each group underwent angiography with digital three-dimensional reconstruction of the aortic bifurcation prior to sacrifice. RESULTS: 1) Blood pressure, heart rate and pulse pressure between the groups with and without nephrectomy showed statistically significant differences (p <0.05). The specimens collected in groups III and IV who received sodium overload developed a hemodynamic pattern characterized by increased heart rate and pulse pressure. 2) Six specimens (60%) in group IV developed aneurysmatic dilatation of the apex of the aortic bifurcation. 3) The angiographic evaluation showed that the morphology of the bifurcation of the control group remains unchanged during the study period. However, group II presents data from longitudinal remodeling with tortuosity and lengthening of the trunk and branches that make up the fork. The Group III presents stenosis and proximal dilatation of the apex of the bifurcation in a pattern described as blister-like. Finally, Group IV shows multiple stenosis proximal and distal to the flow divider. CONCLUSIONS: In murine models, the geometry deformation introduced by changes in the angle of bifurcation, induce inflammation of the flow divider, whereas, high blood pressure, pulse pressure, heart rate and high sodium overload catalyze the aneurysmatic dilatation of these segments (AU)