Abstract
BackgroundThe purpose of this study was to clarify the effect of asymmetric COW variants on carotid flow changes, and proposed an easy estimate of the representative carotid flow volume for accurate numerical simulation.MethodsA total of 210 healthy adults receiving magnetic resonance angiography and carotid duplex sonography were included. Three anterior cerebral artery asymmetry (AA) groups were defined based on the diameter ratio difference (DRD) of bilateral A1 segments: AA1 group, one-side A1 aplasia; AA2, A1 DRD ≥ 50%; AA3, A1 DRD between 10 and 50%. Similarly, 3 posterior communicating artery (PcomA) asymmetry (PA) groups were defined: PA1 group, one fetal-origin posterior cerebral artery and absent contralateral PcomA; PA2, PcomA DRD ≥ 50%; PA3, PcomA DRD between 10 and 50%.ResultsWith A1 asymmetry, the ICA diameter of the dominant A1 is significantly greater than the contralateral side. Significant differences of bilateral ICA flow were present in the AA1 and AA2 groups (mean flow difference 42.9 and 30.7%, respectively). Significant bilateral ICA diameter and flow differences were only found in the PA1 group. Linear regression analysis of ICA diameter and flow found a moderately positive correlation between ICA diameter and flow in all AA groups, with a 1 mm increment in vessel diameter corresponding to a 62.6 ml increment of flow volume. The product of bilateral ICA diameter and flow volume difference (ICA-PDF) could be a potential discriminator with a cutoff of 4.31 to predict A1 asymmetry ≥50% with a sensitivity of 0.81 and specificity of 0.76.ConclusionsThe study verifies that A1 asymmetry causes unequal bilateral carotid inflow, and consequently different bilateral ICA diameters. Adjustment of the inflow boundary conditions according to the COW variants would be necessary to improve the accuracy of numerical simulation.
Highlights
The purpose of this study was to clarify the effect of asymmetric Circle of Willis (COW) variants on carotid flow changes, and proposed an easy estimate of the representative carotid flow volume for accurate numerical simulation
There was a moderately positive association between Internal carotid artery (ICA) vessel diameter and ICA flow volume in the artery asymmetry (AA) groups, with a 1 mm increment in vessel diameter corresponding to a 62.6 ml increment of flow volume
While the COW serves as an important intracranial collateral pathway, there are multiple incomplete or asymmetric variants with variable prevalence according to different classification criteria, including The 1st segment of anterior cerebral artery (A1) absence (2.6–15.4%; 9% in our study), A1 hypoplasia (2.6–28.9%; 15.7% in our study), true fetal posterior cerebral artery (F-PCA) without a The 1st segment of posterior cerebral artery (P1) segment (0.9–29.5%; 10.7% in our study), and F-PCA with P1 hypoplasia (4.5–37.2%; 4.5% in our study) [9,10,11,12, 14, 15, 17, 18, 21,22,23]
Summary
The purpose of this study was to clarify the effect of asymmetric COW variants on carotid flow changes, and proposed an easy estimate of the representative carotid flow volume for accurate numerical simulation. Essential patient-specific physiologic data, such as flow volume and flow rate of the proximal parent artery, are usually lacking for numerical analysis. Total brain blood flow and distribution in different COW-types had been proposed [16]. It had been shown that inflow boundary condition [3, 19], especially parent artery flow volume and the conjoint inflow ratio, affect the hemodynamic parameters of cerebral aneurysms. Adjustment of inflow boundary conditions for cerebral aneurysm analysis according to different COW types is important for obtaining reliable simulation results
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