M
Mahsa Dabagh
Researcher at Lappeenranta University of Technology
Publications - 33
Citations - 504
Mahsa Dabagh is an academic researcher from Lappeenranta University of Technology. The author has contributed to research in topics: Shear stress & Aortic arch. The author has an hindex of 9, co-authored 30 publications receiving 391 citations. Previous affiliations of Mahsa Dabagh include Emory University & Duke University.
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Effect of rheological models on the hemodynamics within human aorta: CFD study on CT image-based geometry
Safoora Karimi,Safoora Karimi,Mahsa Dabagh,P. Vasava,Mitra Dadvar,Bahram Dabir,Payman Jalali +6 more
TL;DR: Comparing the local shear stress magnitude in three branches at different critical cardiac instants shows that the shear thinning nature of blood can slightly influence WSS at diastole, in all branches.
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Finite element modelling of pulsatile blood flow in idealized model of human aortic arch: study of hypotension and hypertension.
TL;DR: The assessment of hemodynamics shows that under the flow regimes of hypotension and hypertension, the risk of atherosclerosis localization in human aorta may increase, and the focus is on variation of wall shear stress.
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The transport of LDL across the deformable arterial wall: the effect of endothelial cell turnover and intimal deformation under hypertension
TL;DR: A multilayered model of the aortic wall is introduced to investigate the transport of low-density lipoprotein (LDL) under hypertension, taking into account the influences of increased endothelial cell turnover and deformation of the intima at higher pressure, capable of making many realistic predictions.
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Effects of polydimethylsiloxane grafting on the calcification, physical properties, and biocompatibility of polyurethane in a heart valve
TL;DR: Evaluated grafting of silicone rubber to the surface of polyurethane successfully prevented the calcification process and the morphology of fibroblast cells that adhered to the PU films and modified films was similar to that of controls and showed the same proliferation.
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Mechanotransmission in endothelial cells subjected to oscillatory and multi-directional shear flow.
TL;DR: The objective of this study is to investigate computationally how the flow direction influences the forces experienced by structural components of ECs that are believed to play important roles in mechanotransduction.