V. Azizi Tarksalooyeh scite author profile

V. Azizi Tarksalooyeh

3Publications

11Citation Statements Received

87Citation Statements Given

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Affiliations

University of Amsterdam

Publications

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Cell-resolved blood flow simulations of saccular aneurysms: effects of pulsatility and aspect ratio

Czaja

Závodszky

Tarksalooyeh

et al. 2018

J. R. Soc. Interface.

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We study the effect of pulsatile flow on the transport of red blood cells (RBCs) and platelets into aneurysm geometries with varying dome-to-neck aspect ratios (AR). We use a validated two-dimensional lattice Boltzmann model for blood plasma with a discrete element method for both RBCs and platelets coupled by the immersed boundary method. Flow velocities and vessel diameters were matched with measurements of cerebral perforating arteries and flow was driven by a synthetic heartbeat curve typical for such vessel sizes. We observe a flow regime change as the aspect ratio increases from a momentum-driven regime in the small aspect ratio to a shear-driven regime in the larger aspect ratios. In the small aspect ratio case, we see the development of a re-circulation zone that exhibits a layering of high (greater than or equal to 7 s) and low (less than 7 s) residence cells. In the shear-driven regime, we see high and low residence cells well mixed, with an increasing population of cells that are trapped inside the aneurysm as the aspect ratio increases. In all cases, we observe aneurysms that are platelet-rich and red blood cell-poor when compared with their respective parental vessel populations. Pulsatility also plays a role in the small aspect ratio as we observe a smaller population of older trapped cells along the aneurysm wall in the pulsatile case when compared with a steady flow case. Pulsatility does not have a significant effect in shear-driven regime aspect ratios.

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Optimizing Parallel Performance of the Cell Based Blood Flow Simulation Software HemoCell

Tarksalooyeh

Závodszky

Hoekstra

2019

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Large scale cell based blood flow simulations are expensive, both in time and resource requirements. HemoCell can perform such simulations on high performance computing resources by dividing the simulation domain into multiple blocks. This division has a performance impact caused by the necessary communication between the blocks. In this paper we implement an efficient algorithm for computing the mechanical model for HemoCell together with an improved communication structure. The result is an up to 4 times performance increase for blood flow simulations performed with HemoCell.

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Supplementary material from "Cell-resolved blood flow simulations of saccular aneurysms: effects of pulsatility and aspect ratio"

Czaja¹,

Závodszky²,

Tarksalooyeh³

et al. 2018

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