In silico analysis of the invasion mechanics and invasiveness of the plasmodium falciparum merozoite
In silico analysis of the invasion mechanics and invasiveness of the plasmodium falciparum merozoite
Although there has been considerable progress in understanding the factors that determine the invasiveness of plasmodium falciparum merozoites, the collective role of the biophysical characteristics of erythrocyte deformability in the invasion process is poorly understood. Cell shape, cytoplasmic viscosity, and membrane stability are the main determinants of erythrocyte deformability, but it remains unknown how these properties affect the merozoite invasiveness. This study aimed to investigate computationally (i) the role of erythrocyte morphology and merozoite-induced erythrocyte membrane damage in merozoite invasion and (ii) the suitability of mechanical markers of merozoite-induced erythrocyte membrane damage for screening of invasion-blocking antimalarial drugs. Finite element models were developed to represent a human erythrocyte and a spherocyte, their invasion by a malaria merozoite, and erythrocyte compression and nanoindentation as mechanical assays for membrane damage. Smoothed particle hydrodynamics represented the erythrocyte cytoplasm, and merozoite-induced erythrocyte membrane damage was implemented with a constitutive model. The invasiveness of the merozoite decreases with increased erythrocyte sphericity associated with genetic disorders such as hereditary spherocytosis. The invasiveness is larger when membrane damage is induced in the erythrocyte at an early invasion stage than throughout the invasion process. The minimum force required for a malaria merozoite to invade a human erythrocyte was predicted to be 11 pN. The findings on the invasion mechanics can guide future studies into the invasiveness of the merozoite. The nanoindentation simulations point to the potential of nanoindentation to determine erythrocyte membrane damage for screening novel invasion-blocking anti-malaria drugs.
Erythrocyte, hereditary spherocytosis, Malaria, Finite Element method, Smoothed particle hydrodyynamics, Drug screening
Msosa, Chimwemwe
1d20ea32-0103-4a15-a639-cd225f82539f
Abdalrahman, Tamer
65d60fa0-5278-4158-9e58-a75854a2c4c1
Franz, Thomas
31f508f4-6851-4274-b256-cc01ab321d50
17 April 2026
Msosa, Chimwemwe
1d20ea32-0103-4a15-a639-cd225f82539f
Abdalrahman, Tamer
65d60fa0-5278-4158-9e58-a75854a2c4c1
Franz, Thomas
31f508f4-6851-4274-b256-cc01ab321d50
Msosa, Chimwemwe, Abdalrahman, Tamer and Franz, Thomas
(2026)
In silico analysis of the invasion mechanics and invasiveness of the plasmodium falciparum merozoite.
Biomechanics and Modeling in Mechanobiology, 25, [39].
(doi:10.1007/s10237-026-02062-w).
Abstract
Although there has been considerable progress in understanding the factors that determine the invasiveness of plasmodium falciparum merozoites, the collective role of the biophysical characteristics of erythrocyte deformability in the invasion process is poorly understood. Cell shape, cytoplasmic viscosity, and membrane stability are the main determinants of erythrocyte deformability, but it remains unknown how these properties affect the merozoite invasiveness. This study aimed to investigate computationally (i) the role of erythrocyte morphology and merozoite-induced erythrocyte membrane damage in merozoite invasion and (ii) the suitability of mechanical markers of merozoite-induced erythrocyte membrane damage for screening of invasion-blocking antimalarial drugs. Finite element models were developed to represent a human erythrocyte and a spherocyte, their invasion by a malaria merozoite, and erythrocyte compression and nanoindentation as mechanical assays for membrane damage. Smoothed particle hydrodynamics represented the erythrocyte cytoplasm, and merozoite-induced erythrocyte membrane damage was implemented with a constitutive model. The invasiveness of the merozoite decreases with increased erythrocyte sphericity associated with genetic disorders such as hereditary spherocytosis. The invasiveness is larger when membrane damage is induced in the erythrocyte at an early invasion stage than throughout the invasion process. The minimum force required for a malaria merozoite to invade a human erythrocyte was predicted to be 11 pN. The findings on the invasion mechanics can guide future studies into the invasiveness of the merozoite. The nanoindentation simulations point to the potential of nanoindentation to determine erythrocyte membrane damage for screening novel invasion-blocking anti-malaria drugs.
Text
P093 Manuscript 3 Chim with EMD rev06 clean
- Accepted Manuscript
Text
s10237-026-02062-w
- Version of Record
More information
Accepted/In Press date: 6 March 2026
e-pub ahead of print date: 17 April 2026
Published date: 17 April 2026
Keywords:
Erythrocyte, hereditary spherocytosis, Malaria, Finite Element method, Smoothed particle hydrodyynamics, Drug screening
Identifiers
Local EPrints ID: 511248
URI: http://eprints.soton.ac.uk/id/eprint/511248
ISSN: 1617-7959
PURE UUID: 0cbe576c-f2e4-43c7-8ad3-cfd60be6da39
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Date deposited: 08 May 2026 17:07
Last modified: 08 May 2026 17:09
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Contributors
Author:
Chimwemwe Msosa
Author:
Tamer Abdalrahman
Author:
Thomas Franz
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