Journal
SOFT MATTER
Volume 18, Issue 9, Pages 1747-1756Publisher
ROYAL SOC CHEMISTRY
DOI: 10.1039/d1sm01542g
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Funding
- EPSRC [EP/R513179/1]
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In order to accurately represent the morphological and elastic properties of a human red blood cell, Fu et al. developed a coarse-grained molecular dynamics model. By simulating cells of different diameters, they assessed the validity of the model and found that cells with a diameter of at least 0.5μm were able to form the characteristic shape of human red blood cells.
To accurately represent the morphological and elastic properties of a human red blood cell, Fu et al. [Fu et al., Lennard-Jones type pair-potential method for coarse-grained lipid bilayer membrane simulations in LAMMPS, 2017, 210, 193-203] recently developed a coarse-grained molecular dynamics model with particular detail in the membrane. However, such a model accrues an extremely high computational cost for whole-cell simulation when assuming an appropriate length scaling - that of the bilayer thickness. To date, the model has only simulated miniature cells in order to circumvent this, with the a priori assumption that these miniaturised cells correctly represent their full-sized counterparts. The present work assesses the validity of this approach, by testing the scale invariance of the model through simulating cells of various diameters; first qualitatively in their shape evolution, then quantitatively by measuring their bending rigidity through fluctuation analysis. Cells of diameter of at least 0.5 mu m were able to form the characteristic biconcave shape of human red blood cells, though smaller cells instead equilibrated to bowl-shaped stomatocytes. Thermal fluctuation analysis showed the bending rigidity to be constant over all cell sizes tested, and consistent between measurements on the whole-cell and on a planar section of bilayer. This is as expected from the theory on both counts. Therefore, we confirm that the evaluated model is a good representation of a full-size RBC when the model diameter is >= 0.5 mu m, in terms of the morphological and mechanical properties investigated.
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