A peculiar thin layer of clear plasma, devoid of red blood cells exists adjacent to the walls of our arterioles, capillaries, and venules -- the blood vessels that make up our microcirculation.

Red blood cells, which make up 45 percent of blood, normally take the shape of circular cushions with a dimple on either side. But they can sometimes deform into an asymmetrical slipper shape.

Several red blood cell disorders can decrease the effectiveness of a person’s red blood cells. These include anemia, polycythemia, sickle cell disease, thalassemia, and malaria.

Understanding red blood cell assemblies under flow is essential to deciphering many blood and cardiovascular pathologies, the main cause of mortality in the world. The research team’s findings unlock ...

Why blood cells move in slippers. Timm Krüger of the University of Edinburgh told Physics World that an important strength of the research is that it “used two different and quite different modelling ...

A new computer model can predict red blood cell flow and holds potential for improving treatment for trauma injuries, according to research published recently in the journal Physics of Fluids. | A ...

Sickle cell disease is a group of inherited disorders that affect the hemoglobin, which causes sickle-shaped red blood cells. Learn about the symptoms, causes and treatment.

Computer model predicts red blood cell flow. ScienceDaily. Retrieved June 2, 2025 from www.sciencedaily.com / releases / 2013 / 08 / 130813130337.htm. American Institute of Physics (AIP).

WASHINGTON D.C. August 13, 2013 -- Adjacent to the walls of our arterioles, capillaries, and venules -- the blood vessels that make up our microcirculation -- there exists a peculiar thin layer of ...

Aug 13, 2013: Computer model predicts red blood cell flow (Nanowerk News) Adjacent to the walls of our arterioles, capillaries, and venules -- the blood vessels that make up our microcirculation -- ...