Optimal hematocrit $H_o$ maximizes oxygen transport. In healthy humans, the
average hematocrit $H$ is in the range of 40-45$\%$, but it can significantly
change in blood pathologies such as severe anemia (low $H$) and polycythemia
(high $H$). Whether the hematocrit level in humans corresponds to the optimal
one is a long standing physiological question. Here, using numerical
simulations with the Lattice Boltzmann method and two mechanical models of the
red blood cell (RBC) we predict the optimal hematocrit, and explore how
altering the mechanical properties of RBCs affects $H_o$. We develop a
simplified analytical theory that accounts for results obtained from numerical
simulations and provides insight into the physical mechanisms determining
$H_o$. Our numerical and analytical models can easily be modified to
incorporate a wide range of mechanical properties of RBCs as well as other soft
particles thereby providing means for the rational design of blood substitutes.
Our work lays the foundations for systematic theoretical study of the optimal
hematocrit and its link with pathological RBCs associated with various diseases
(e.g. sickle cell anemia, diabetes mellitus, malaria, elliptocytosis)

Audemar, Vassanti

Benyoussef, Abdelilah

Coupier, Gwennou

Ez-Zahraouy, Hamid

Farutin, Alexander

Harting, Jens

Misbah, Chaouqi

Podgorski, Thomas

Polack, Benoit

Prado, Gael

Shen, Zaiyi

Vlahovska, Petia M.

English

arXiv

Flux of rigid or soft particles (such as drops, vesicles, red blood cells, etc.) in a channel is a complex function of particle concentration, which depends on the details of induced dissipation and suspension structure due to hydrodynamic interactions with walls or between neighboring particles. Through two-dimensional and three-dimensional simulations and a simple model that reveals the contribution of the main characteristics of the flowing suspension, we discuss the existence of an optimal volume fraction for cell transport and its dependence on the cell mechanical properties. The example of blood is explored in detail, by adopting the commonly used modeling of red blood cells dynamics. We highlight the complexity of optimization at the level of a network, due to the antagonist evolution of local volume fraction and optimal volume fraction with the channels diameter. In the case of the blood network, the most recent results on the size evolution of vessels along the circulatory network of healthy organs suggest that the red blood cell volume fraction (hematocrit) of healthy subjects is close to optimality, as far as transport only is concerned. However, the hematocrit value of patients suffering from diverse red blood cel pathologies may strongly deviate from optimality.</p

University of Twente Research Information

Optimal cell transport in straight channels and networks

International audienceFlux of rigid or soft particles (such as drops, vesicles, red blood cells, etc.) in a channel is a complex function of particle concentration, which depends on the details of induced dissipation and suspension structure due to hydrodynamic interactions with walls or between neighboring particles. Through two-dimensional and three-dimensional simulations and a simple model that reveals the contribution of the main characteristics of the flowing suspension, we discuss the existence of an optimal volume fraction for cell transport and its dependence on the cell mechanical properties. The example of blood is explored in detail, by adopting the commonly used modeling of red blood cells dynamics. We highlight the complexity of optimization at the level of a network, due to the antagonist evolution of local volume fraction and optimal volume fraction with the channels diameter. In the case of the blood network, the most recent results on the size evolution of vessels along the circulatory network of healthy organs suggest that the red blood cell volume fraction (hematocrit) of healthy subjects is close to optimality, as far as transport only is concerned. However, the hematocrit value of patients suffering from diverse red blood cel pathologies may strongly deviate from optimality

Prado, Gaël

Vlahovska, Petia, M

HAL: Hyper Article en Ligne

Flux of rigid or soft particles (such as drops, vesicles, red blood cells, etc.) in a channel is a complex function of particle concentration, which depends on the details of induced dissipation and suspension structure due to hydrodynamic interactions with walls or between neighboring particles. Through two-dimensional and three-dimensional simulations and a simple model that reveals the contribution of the main characteristics of the flowing suspension, we discuss the existence of an optimal volume fraction for cell transport and its dependence on the cell mechanical properties. The example of blood is explored in detail, by adopting the commonly used modeling of red blood cells dynamics. We highlight the complexity of optimization at the level of a network, due to the antagonist evolution of local volume fraction and optimal volume fraction with the channels diameter. In the case of the blood network, the most recent results on the size evolution of vessels along the circulatory network of healthy organs suggest that the red blood cell volume fraction (hematocrit) of healthy subjects is close to optimality, as far as transport only is concerned. However, the hematocrit value of patients suffering from diverse red blood cel pathologies may strongly deviate from optimality

NARCIS 

Pure OAI Repository

\u3cp\u3eFlux of rigid or soft particles (such as drops, vesicles, red blood cells, etc.) in a channel is a complex function of particle concentration, which depends on the details of induced dissipation and suspension structure due to hydrodynamic interactions with walls or between neighboring particles. Through two-dimensional and three-dimensional simulations and a simple model that reveals the contribution of the main characteristics of the flowing suspension, we discuss the existence of an optimal volume fraction for cell transport and its dependence on the cell mechanical properties. The example of blood is explored in detail, by adopting the commonly used modeling of red blood cells dynamics. We highlight the complexity of optimization at the level of a network, due to the antagonist evolution of local volume fraction and optimal volume fraction with the channels diameter. In the case of the blood network, the most recent results on the size evolution of vessels along the circulatory network of healthy organs suggest that the red blood cell volume fraction (hematocrit) of healthy subjects is close to optimality, as far as transport only is concerned. However, the hematocrit value of patients suffering from diverse red blood cel pathologies may strongly deviate from optimality.\u3c/p\u3

Shen, Z Zaiyi

Polack, B Benoît

Harting, JDR Jens

Vlahovska, Petia M

Podgorski, T Thomas

Coupier, G Gwennou

Misbah, C Chaouqi

Repository TU/e

Juelich Shared Electronic Resources

https://research.utwente.nl/en/publications/2e6611e9-24b2-4470-97c5-bdf0182cde01