Abstract
Idiopathic intracranial hypertension has been associated with dural venous sinus stenosis in some patients, but the hemodynamic environment of the dural venous sinuses has not been quantitatively described. Here, we present the first such computational fluid dynamics model by using patient-specific blood pressure measurements. Six patients with idiopathic intracranial hypertension and at least 1 stenosis or atresia at the transverse/sigmoid sinus junction underwent MR venography followed by cerebral venography and manometry throughout the dural venous sinuses. Patient-specific computational fluid dynamics models were created by using MR venography anatomy, with venous pressure measurements as boundary conditions. Blood flow and wall shear stress were calculated for each patient. Computational models of the dural venous sinuses were successfully reconstructed in all 6 patients with patient-specific boundary conditions. Three patients demonstrated a pathologic pressure gradient (≥8 mm Hg) across 4 dural venous sinus stenoses. Small sample size precludes statistical comparisons, but average overall flow throughout the dural venous sinuses of patients with pathologic pressure gradients was higher than in those without them (1041.00 ± 506.52 mL/min versus 358.00 ± 190.95 mL/min). Wall shear stress was also higher across stenoses in patients with pathologic pressure gradients (37.66 ± 48.39 Pa versus 7.02 ± 13.60 Pa). The hemodynamic environment of the dural venous sinuses can be computationally modeled by using patient-specific anatomy and physiologic measurements in patients with idiopathic intracranial hypertension. There was substantially higher blood flow and wall shear stress in patients with pathologic pressure gradients.
Highlights
BACKGROUND AND PURPOSEIdiopathic intracranial hypertension has been associated with dural venous sinus stenosis in some patients, but the hemodynamic environment of the dural venous sinuses has not been quantitatively described
The hemodynamic environment of the dural venous sinuses can be computationally modeled by using patient-specific anatomy and physiologic measurements in patients with idiopathic intracranial hypertension
That some patients with intracranial hypertension (IIH) present with this pressure gradient and others do not, despite similar anatomic narrowing of the dural venous sinuses, suggests that the mechanism by which IIH is related to venous sinus stenosis may depend on hemodynamic characteristics of dural venous sinus drainage.[6]
Summary
Six patients with idiopathic intracranial hypertension and at least 1 stenosis or atresia at the transverse/ sigmoid sinus junction underwent MR venography followed by cerebral venography and manometry throughout the dural venous sinuses. Six patients with a previous diagnosis of untreated IIH (determined by intracranial pressure of Ն25 cm H2O without structural or CSF abnormality7) and MR venography demonstrating dural venous sinus atresia or stenosis of Ͼ50% in at least 1 location underwent cerebral venography with manometry. Manometry was performed in the bilateral transverse and sigmoid sinuses and the posterior third of the superior sagittal sinus by transducing the blood pressure through the microcatheter. In 2 patients in whom the transverse and sigmoid sinuses were atretic or absent on 1 side, measurements were obtained in all other locations. Patients were grouped into pathologic and nonpathologic groups based on the presence of such a gradient across Ն1 stenotic venous sinus
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