Band pattern formation of erythrocytes in density gradients is due to competing aggregation and net buoyancy

Felix Maurer; Camila Romero; Nikolas Lerch; Thomas John; Lars Kaestner; Christian Wagner; Alexis Darras

doi:10.1073/pnas.2515704122

Band pattern formation of erythrocytes in density gradients is due to competing aggregation and net buoyancy

Felix Maurer^*, Camila Romero, Nikolas Lerch, Thomas John, Lars Kaestner, Christian Wagner, Alexis Darras^*

^*Corresponding author for this work

School of Physics

Research output: Contribution to journal › Article (Academic Journal) › peer-review

Abstract

Centrifugation of biological matter in density gradient solutions is a standard method for separating cell types or components. It is also used to separate red blood cells (RBCs) by age, as they lose water and become denser over their lifespan. When the density gradient is prepared with Percoll, discrete bands of RBCs are systematically observed along the gradient, despite the continuous density distribution of RBCs. Early studies suggested that cell aggregation might influence spatial distribution, but it remains debated whether a continuous density population can form discrete bands. We developed a continuity equation incorporating cell aggregation to describe the macroscopic evolution of RBC volume fraction in a density gradient, considering a continuous RBC density distribution. Numerical solutions demonstrate that the competition between net buoyancy and aggregation is sufficient to create band patterns. Our model reproduces the temporal evolution observed in experiments, but also predicts several types of bifurcation-like behaviors for the steady-state patterns in constant gradients, depending on RBC volume fraction and aggregation energy. This demonstrates that the competition between RBC aggregation and net buoyancy is a mechanism driving pattern formation.

Original language	English
Article number	e2515704122
Number of pages	8
Journal	Proceedings of the National Academy of Sciences
Volume	122
Issue number	51
DOIs	https://doi.org/10.1073/pnas.2515704122
Publication status	Published - 19 Dec 2025

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title = "Band pattern formation of erythrocytes in density gradients is due to competing aggregation and net buoyancy",

abstract = "Centrifugation of biological matter in density gradient solutions is a standard method for separating cell types or components. It is also used to separate red blood cells (RBCs) by age, as they lose water and become denser over their lifespan. When the density gradient is prepared with Percoll, discrete bands of RBCs are systematically observed along the gradient, despite the continuous density distribution of RBCs. Early studies suggested that cell aggregation might influence spatial distribution, but it remains debated whether a continuous density population can form discrete bands. We developed a continuity equation incorporating cell aggregation to describe the macroscopic evolution of RBC volume fraction in a density gradient, considering a continuous RBC density distribution. Numerical solutions demonstrate that the competition between net buoyancy and aggregation is sufficient to create band patterns. Our model reproduces the temporal evolution observed in experiments, but also predicts several types of bifurcation-like behaviors for the steady-state patterns in constant gradients, depending on RBC volume fraction and aggregation energy. This demonstrates that the competition between RBC aggregation and net buoyancy is a mechanism driving pattern formation.",

author = "Felix Maurer and Camila Romero and Nikolas Lerch and Thomas John and Lars Kaestner and Christian Wagner and Alexis Darras",

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T1 - Band pattern formation of erythrocytes in density gradients is due to competing aggregation and net buoyancy

AU - Maurer, Felix

AU - Romero, Camila

AU - Lerch, Nikolas

AU - John, Thomas

AU - Kaestner, Lars

AU - Wagner, Christian

AU - Darras, Alexis

PY - 2025/12/19

Y1 - 2025/12/19

N2 - Centrifugation of biological matter in density gradient solutions is a standard method for separating cell types or components. It is also used to separate red blood cells (RBCs) by age, as they lose water and become denser over their lifespan. When the density gradient is prepared with Percoll, discrete bands of RBCs are systematically observed along the gradient, despite the continuous density distribution of RBCs. Early studies suggested that cell aggregation might influence spatial distribution, but it remains debated whether a continuous density population can form discrete bands. We developed a continuity equation incorporating cell aggregation to describe the macroscopic evolution of RBC volume fraction in a density gradient, considering a continuous RBC density distribution. Numerical solutions demonstrate that the competition between net buoyancy and aggregation is sufficient to create band patterns. Our model reproduces the temporal evolution observed in experiments, but also predicts several types of bifurcation-like behaviors for the steady-state patterns in constant gradients, depending on RBC volume fraction and aggregation energy. This demonstrates that the competition between RBC aggregation and net buoyancy is a mechanism driving pattern formation.

AB - Centrifugation of biological matter in density gradient solutions is a standard method for separating cell types or components. It is also used to separate red blood cells (RBCs) by age, as they lose water and become denser over their lifespan. When the density gradient is prepared with Percoll, discrete bands of RBCs are systematically observed along the gradient, despite the continuous density distribution of RBCs. Early studies suggested that cell aggregation might influence spatial distribution, but it remains debated whether a continuous density population can form discrete bands. We developed a continuity equation incorporating cell aggregation to describe the macroscopic evolution of RBC volume fraction in a density gradient, considering a continuous RBC density distribution. Numerical solutions demonstrate that the competition between net buoyancy and aggregation is sufficient to create band patterns. Our model reproduces the temporal evolution observed in experiments, but also predicts several types of bifurcation-like behaviors for the steady-state patterns in constant gradients, depending on RBC volume fraction and aggregation energy. This demonstrates that the competition between RBC aggregation and net buoyancy is a mechanism driving pattern formation.

U2 - 10.1073/pnas.2515704122

DO - 10.1073/pnas.2515704122

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JO - Proceedings of the National Academy of Sciences

JF - Proceedings of the National Academy of Sciences

IS - 51

M1 - e2515704122

ER -

Band pattern formation of erythrocytes in density gradients is due to competing aggregation and net buoyancy

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