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(Stroke. 2005;36:2696.)
© 2005 American Heart Association, Inc.

Original Contributions

Hemodynamic Evaluation of Embolic Trajectory in an Arterial Bifurcation

An In-Vitro Experimental Model

Doron Bushi, MSc; Ygael Grad, PhD; Shmuel Einav, PhD; Ofer Yodfat, MD; Boaz Nishri, PhD David Tanne, MD

From the Department of Biomedical-Engineering (D.B., Y.G., S.E.), Tel-Aviv University, Tel-Aviv; the MindGuard Ltd (D.B., Y.G., O.Y., B.N.), Caesarea, Israel; and the Stroke Center (D.T.), Sheba Medical Center, Tel-Hashomer and Tel-Aviv University, Tel-Aviv, Israel

Correspondence to Doron Bushi, MSc, Hhistadroot 23, Holon 58319, Israel. E-mail doron_bushi{at}walla.com

Background and Purpose— Despite the importance of embolism as a major cause of brain infarction, little is known about the hemodynamic factors governing the path large emboli tend to follow. Our aim was to test in vitro, whether hemodynamic parameters other than flow ratios between bifurcation branches may affect the distribution of embolic particles in a Y-shaped bifurcation model, used as an analogue to an arterial bifurcation.

Methods— In vitro experiments were conducted using suspensions of sphere-shaped particles (0.6, 1.6, and 3.2 mm) in water-glycerin mixture, using steady and pulsatile laminar flow regimes in a Y-shaped bifurcation model (identical branching angles [₁=₂=45^o] with one daughter branch diameter wider than the other [D₁=6 mm, D₂=4 mm]; average Reynolds number 500).

Results— Experiments using naturally buoyant particles under steady flow conditions and four outlet-flow ratios revealed that small (0.6 mm) and mid-sized (1.6 mm) particles entered into either the narrower or wider bifurcation daughter branch nonpreferentially, proportionally to the flow ratios. Large particles (3.2 mm), however, preferentially entered the wider daughter branch. Moreover, as the flow ratio increases this phenomenon was augmented. Further experiments revealed that the preference of the wider daughter branch for high particle-to-branch diameter-ratios further increases under pulsatile flow and by the density ratio between particles and fluid.

Conclusion— Particles’ distribution in a bifurcation is affected, beyond its outlets-flow-ratios, by the particle-to-branch diameter-ratio. The tendency of large particles to preferentially enter the wider bifurcation branch, beyond the flow ratio, is augmented under pulsatile flow conditions and is affected by particle-to-fluid density-ratio. These findings may have important implications for understanding the hemodynamic mechanisms underlying the trajectory of large emboli.

Key Words: embolism • experimental • hemodynamics

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