Toward an Optimal Position for IVC Filters: Computational Modeling of the Impact of Renal Vein Inflow

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The purpose of this report is to evaluate the hemodynamic effects of renal vein inflow and filter position on unoccluded and partially occluded IVC filters using three-dimensional computational fluid dynamics. Three-dimensional models of the TrapEase and Gunther Celect IVC filters, spherical thrombi, and an IVC with renal veins were constructed. Hemodynamics of steady-state flow was examined for unoccluded and partially occluded TrapEase and Gunther Celect IVC filters in varying proximity to the renal veins. Flow past the unoccluded filters demonstrated minimal disruption. Natural regions of stagnant/recirculating flow in the IVC are observed superior to the bilateral renal vein inflows, and ... continued below

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Wang, S L & Singer, M A July 13, 2009.

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The purpose of this report is to evaluate the hemodynamic effects of renal vein inflow and filter position on unoccluded and partially occluded IVC filters using three-dimensional computational fluid dynamics. Three-dimensional models of the TrapEase and Gunther Celect IVC filters, spherical thrombi, and an IVC with renal veins were constructed. Hemodynamics of steady-state flow was examined for unoccluded and partially occluded TrapEase and Gunther Celect IVC filters in varying proximity to the renal veins. Flow past the unoccluded filters demonstrated minimal disruption. Natural regions of stagnant/recirculating flow in the IVC are observed superior to the bilateral renal vein inflows, and high flow velocities and elevated shear stresses are observed in the vicinity of renal inflow. Spherical thrombi induce stagnant and/or recirculating flow downstream of the thrombus. Placement of the TrapEase filter in the suprarenal vein position resulted in a large area of low shear stress/stagnant flow within the filter just downstream of thrombus trapped in the upstream trapping position. Filter position with respect to renal vein inflow influences the hemodynamics of filter trapping. Placement of the TrapEase filter in a suprarenal location may be thrombogenic with redundant areas of stagnant/recirculating flow and low shear stress along the caval wall due to the upstream trapping position and the naturally occurring region of stagnant flow from the renal veins. Infrarenal vein placement of IVC filters in a near juxtarenal position with the downstream cone near the renal vein inflow likely confers increased levels of mechanical lysis of trapped thrombi due to increased shear stress from renal vein inflow.

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PDF-file: 26 pages; size: 1.6 Mbytes

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  • Journal Name: Journal of Vascular and Interventional Radiology, vol. 21, no. 3, March 1, 2010, pp. 367-374; Journal Volume: 21; Journal Issue: 3

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  • Report No.: LLNL-JRNL-414674
  • Grant Number: W-7405-ENG-48
  • Office of Scientific & Technical Information Report Number: 973636
  • Archival Resource Key: ark:/67531/metadc928444

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  • July 13, 2009

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  • Nov. 13, 2016, 7:26 p.m.

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  • Dec. 9, 2016, midnight

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Wang, S L & Singer, M A. Toward an Optimal Position for IVC Filters: Computational Modeling of the Impact of Renal Vein Inflow, article, July 13, 2009; Livermore, California. (digital.library.unt.edu/ark:/67531/metadc928444/: accessed April 21, 2018), University of North Texas Libraries, Digital Library, digital.library.unt.edu; crediting UNT Libraries Government Documents Department.