Physiological Fluid Mechanics II: Small Vessels and Microcirculation

Presentations

• Deep representation and unsupervised learning for the experimental analysis of rigid particle margination in red blood cell flows

  ORAL

  Nov. 25, 2024, 6:45 PM – Nov. 25, 2024, 6:58 PM

  Presenters

  • Gonçalo Coutinho

    University of Lisbon, Instituto Superior Técnico

  Authors

  • Gonçalo Coutinho

    University of Lisbon, Instituto Superior Técnico

  • Philipp Warlitz

    Karlsruhe Institute of Technology

  • Ana Moita

    University of Lisbon, Instituto Superior Tecnico

  • Jochen Kriegseis

    Karlsruhe Institute of Technology

  • António Moreira

    University of Lisbon, Instituto Superior Tecnico

  • Massimiliano Rossi

    University of Bologna, Alma Mater Studiorum

  View abstract →

• Revisiting the Relevance of Platelet Margination in Arteries: a Computational Investigation

  ORAL

  Nov. 25, 2024, 6:58 PM – Nov. 25, 2024, 7:11 PM

  Publication: [1] P. A. Aarts, S. A. van den Broek, G. W. Prins, G. D. Kuiken, J. J. Sixma, and R. M. Heethaar, "Blood platelets are concentrated near the wall and red blood cells, in the center in flowing blood.," Arteriosclerosis: An Official Journal of the American Heart Association, Inc., vol. 8, no. 6, pp. 819–824, Nov. 1988, doi: 10.1161/01.ATV.8.6.819.
  [2] C. Xu and D. M. Wootton, "Platelet near‐wall excess in porcine whole blood in artery‐sized tubes under steady and pulsatile flow conditions," Biorheology, vol. 41, no. 2, pp. 113–125, Jan. 2004.
  [3] G. Bergström et al., "Prevalence of Subclinical Coronary Artery Atherosclerosis in the General Population," Circulation, vol. 144, no. 12, pp. 916–929, Sep. 2021, doi: 10.1161/CIRCULATIONAHA.121.055340.
  [4] E. C. Eckstein and F. Belgacem, "Model of platelet transport in flowing blood with drift and diffusion terms," Biophysical Journal, vol. 60, no. 1, pp. 53–69, Jul. 1991, doi: 10.1016/S0006-3495(91)82030-6.
  [5] H. Chen et al., "Hematocrit and flow rate regulate the adhesion of platelets to von Willebrand factor," Biomicrofluidics, vol. 7, no. 6, Nov. 2013, doi: 10.1063/1.4833975.
  [6] M. R. Maxey, "Equation of motion for a small rigid sphere in a nonuniform flow," Phys. Fluids, vol. 26, no. 4, p. 883, 1983, doi: 10.1063/1.864230.

  Presenters

  • Arnav Garcha

    Carnegie Mellon University

  Authors

  • Arnav Garcha

    Carnegie Mellon University

  • Noelia Grande Gutiérrez

    Carnegie Mellon University

  View abstract →

• Network analysis of flow in glomeruli

  ORAL

  Nov. 25, 2024, 7:11 PM – Nov. 25, 2024, 7:24 PM

  Presenters

  • Anton Glazkov

    King Abdullah Univ of Sci & Tech (KAUST)

  Authors

  • Anton Glazkov

    King Abdullah Univ of Sci & Tech (KAUST)

  • Peter J Schmid

    King Abdullah University of Science and Technology, King Abdullah Univ of Sci & Tech (KAUST)

  • Dominik Obrist

    University of Bern

  View abstract →

• Abstract Withdrawn

  ORAL Withdrawn

  Nov. 25, 2024, 7:24 PM – Nov. 25, 2024, 7:37 PM

  View abstract →

• New Blood Vessel Sprouts and the Unique Hemodynamics Within

  ORAL

  Nov. 25, 2024, 7:37 PM – Nov. 25, 2024, 7:50 PM

  Publication: Hossain, MMN., Hu, NW., Murfee, WL., and Balogh, P. "Hemodynamics in new 3D blood vessel sprouts based on red blood cell resolved simulations." Submission planned to Physical Review Fluids.

  Presenters

  • Mir Md Nasim Hossain

    New Jersey Institute of Technology

  Authors

  • Mir Md Nasim Hossain

    New Jersey Institute of Technology

  • Ali Kazempour

    New Jersey Institute of Technology

  • Nien-Wen Hu

    University of Florida

  • Walter L Murfee

    University of Florida

  • Peter Balogh

    New Jersey Institute of Technology

  View abstract →

• Hemodynamic Characteristics of a Tortuous In Vivo Microvessel Using Red Blood Cell Resolved Simulations

  ORAL

  Nov. 25, 2024, 7:50 PM – Nov. 25, 2024, 8:03 PM

  Publication: Hossain, M. M. N., Hu, N. W., Kazempour, A., Murfee, W. L., & Balogh, P. (2024). Hemodynamic Characteristics of a Tortuous Microvessel Using High‐Fidelity Red Blood Cell Resolved Simulations. Microcirculation, e12875.

  Presenters

  • Ali Kazempour

    New Jersey Institute of Technology

  Authors

  • Ali Kazempour

    New Jersey Institute of Technology

  • Mir Md Nasim Hossain

    New Jersey Institute of Technology

  • Nien-Wen Hu

    University of Florida

  • Walter L Murfee

    University of Florida

  • Peter Balogh

    New Jersey Institute of Technology

  View abstract →

• Hemodynamic regulation allows stable growth of microvascular networks

  ORAL

  Nov. 25, 2024, 8:03 PM – Nov. 25, 2024, 8:16 PM

  Publication: Qi, Yujia, et al. "Hemodynamic regulation allows stable growth of microvascular networks." Proceedings of the National Academy of Sciences 121.9 (2024): e2310993121.

  Presenters

  • Yujia Qi

    University of Genova

  Authors

  • Yujia Qi

    University of Genova

  • Marcus Roper

    UCLA

  • Shyr-Shea Chang

    University of California, Los Angeles

  • Yixuan Wang

    University of California, Los Angeles

  View abstract →

• Red blood cells transition from single-file to two-file induced by streamline curvature

  ORAL

  Nov. 25, 2024, 8:16 PM – Nov. 25, 2024, 8:29 PM

  Presenters

  • Yu Terada

    The University of Tokyo

  Authors

  • Yu Terada

    The University of Tokyo

  • Tomoaki Watamura

    Univ of Tokyo, The University of Tokyo

  • Satoshi Ii

    Tokyo Institute of Technology

  • Shu Takagi

    Univ of Tokyo, The University of Tokyo

  View abstract →

• Direct comparison between dissipative particle dynamics simulation of blood flow and live imaging in zebrafish vasculature

  ORAL

  Nov. 25, 2024, 8:29 PM – Nov. 25, 2024, 8:42 PM

  Presenters

  • Shun Tomizawa

    The University of Tokyo

  Authors

  • Shun Tomizawa

    The University of Tokyo

  • Vivek Kumar

    The University of Tokyo

  • Hiroyuki Nakajima

    National Cardiovascular Research Center

  • Zhen Li

    Clemson University

  • Yosuke Hasegawa

    The University of Tokyo

  View abstract →