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Results: 53
Number of items: 53
  • Spieker, C. J., Asteriou, K., & Zav́odszky, G. (2023). Simulating Initial Steps of Platelet Aggregate Formation in a Cellular Blood Flow Environment. In J. Mikyška, C. de Mulatier, M. Paszynski, V. V. Krzhizhanovskaya, J. J. Dongarra, & P. M. A. Sloot (Eds.), Computational Science – ICCS 2023: 23rd International Conference, Prague, Czech Republic, July 3–5, 2023 : proceedings (Vol. III, pp. 323-336). (Lecture Notes in Computer Science; Vol. 10475). Springer. https://doi.org/10.1007/978-3-031-36024-4_26
  • Open Access
    van Dijk, J., Zavodszky, G., Varbanescu, A.-L., Pimentel, A. D., & Hoekstra, A. (2023). Building a Fine-Grained Analytical Performance Model for Complex Scientific Simulations. In R. Wyrzykowski, J. Dongarra, E. Deelman, & K. Karczewski (Eds.), Parallel Processing and Applied Mathematics: 14th International Conference, PPAM 2022, Gdansk, Poland, September 11–14, 2022 : revised selected papers (Vol. I, pp. 183-196). (Lecture Notes in Computer Science; Vol. 13826). Springer. https://doi.org/10.1007/978-3-031-30442-2_14
  • Open Access
    Spieker, C. J., Závodszky, G., Mouriaux, C., Mangin, P. H., & Hoekstra, A. G. (2023). Initial platelet aggregation in the complex shear environment of a punctured vessel model. Physics of Fluids, 35(7), Article 071904 . https://doi.org/10.1063/5.0157814
  • Open Access
    Hao, Y., Závodszky, G., Tersteeg, C., Barzegari, M., & Hoekstra, A. G. (2023). Image-based flow simulation of platelet aggregates under different shear rates. PLoS Computational Biology, 19(7), Article e1010965. https://doi.org/10.1371/JOURNAL.PCBI.1010965
  • Czaja, B., de Bouter, J., Heisler, M., Závodszky, G., Karst, S., Sarunic, M., Maberley, D., Hoekstra, A., & Sarunic, M. (2022). The effect of stiffened diabetic red blood cells on wall shear stress in a reconstructed 3D microaneurysm [Data set]. Taylor & Francis. https://doi.org/10.6084/m9.figshare.19228682.v1
  • Kimmerlin, Q., Moog, S., Yakusheva, A., Ziessel, C., Eckly, A., Freund, M., Závodszky, G., Knapp, Y., Mangin, P., & Lanza, F. (2022). Loss of α4A- and β1-tubulins leads to severe platelet spherocytosis and strongly impairs hemostasis in mice. Blood, 140(21), 2290-2299. https://doi.org/10.1182/blood.2022016729
  • Open Access
    Padmos, R. M., Arrarte Terreros, N., Józsa, T. I., Závodszky, G., Marquering, H. A., Majoie, C. B. L. M., Payne, S. J., & Hoekstra, A. G. (2022). Modelling collateral flow and thrombus permeability during acute ischaemic stroke. Journal of the Royal Society Interface, 19(195), Article 20220649. https://doi.org/10.1098/rsif.2022.0649
  • Open Access
    Padmos, R. M. (2022). Modelling cerebral blood flow and perfusion during acute ischaemic stroke. [Thesis, fully internal, Universiteit van Amsterdam].
  • Open Access
    Czaja, B., de Bouter, J., Heisler, M., Závodszky, G., Karst, S., Sarunic, M., Maberley, D., & Hoekstra, A. (2022). The effect of stiffened diabetic red blood cells on wall shear stress in a reconstructed 3D microaneurysm. Computer Methods in Biomechanics and Biomedical Engineering, 25(15), 1691-1709. https://doi.org/10.1080/10255842.2022.2034794
  • Open Access
    Yakusheva, A. A., Butov, K. R., Bykov, G. A., Závodszky, G., Eckly, A., Ataullakhanov, F. I., Gachet, C., Panteleev, M. A., & Mangin, P. H. (2022). Traumatic vessel injuries initiating hemostasis generate high shear conditions. Blood Advances, 6(16), 4834-4846. https://doi.org/10.1182/bloodadvances.2022007550
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