Locomotion of paired spermatozoa during flagellar synchronisation

Kaixuan Zhang; Aaron Lewis; Anke Klingner; Veronika Magdanz; Sarthak Misra; Islam S.M. Khalil

doi:10.1017/jfm.2025.79

Locomotion of paired spermatozoa during flagellar synchronisation

Kaixuan Zhang^*
, Aaron Lewis
, Anke Klingner
, Veronika Magdanz
, Sarthak Misra
, Islam S.M. Khalil^*

^*Corresponding author for this work

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

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Abstract

Microorganisms, such as spermatozoa, exhibit rich behaviours when in close proximity to each other. However, their locomotion is not fully understood when coupled mechanically and hydrodynamically. In this study, we develop hydrodynamic models to investigate the locomotion of paired spermatozoa, predicting the fine structure of their swimming. Experimentally, sperm pairs are observed to transition between different modes of flagellar synchronisation: in-phase, anti-phase and lagged synchronisation. Using our models, we assess their swimming performances in these synchronisation modes in terms of average swimming speed, average power consumption, and swimming efficiency. The swimming performances of paired spermatozoa are shown to depend on their flagellar phase lag, flagellar waveforms, and the mechanical coupling between their heads.

Original language	English
Article number	A43
Journal	Journal of fluid mechanics
Volume	1007
DOIs	https://doi.org/10.1017/jfm.2025.79
Publication status	Published - 25 Mar 2025

Keywords

micro-organism dynamics
propulsion

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10.1017/jfm.2025.79Licence: CC BY

locomotion-of-paired-spermatozoa-during-flagellar-synchronisationFinal published version, 1.94 MBLicence: CC BY

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title = "Locomotion of paired spermatozoa during flagellar synchronisation",

abstract = "Microorganisms, such as spermatozoa, exhibit rich behaviours when in close proximity to each other. However, their locomotion is not fully understood when coupled mechanically and hydrodynamically. In this study, we develop hydrodynamic models to investigate the locomotion of paired spermatozoa, predicting the fine structure of their swimming. Experimentally, sperm pairs are observed to transition between different modes of flagellar synchronisation: in-phase, anti-phase and lagged synchronisation. Using our models, we assess their swimming performances in these synchronisation modes in terms of average swimming speed, average power consumption, and swimming efficiency. The swimming performances of paired spermatozoa are shown to depend on their flagellar phase lag, flagellar waveforms, and the mechanical coupling between their heads.",

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T1 - Locomotion of paired spermatozoa during flagellar synchronisation

AU - Zhang, Kaixuan

AU - Lewis, Aaron

AU - Klingner, Anke

AU - Magdanz, Veronika

AU - Misra, Sarthak

AU - Khalil, Islam S.M.

PY - 2025/3/25

Y1 - 2025/3/25

N2 - Microorganisms, such as spermatozoa, exhibit rich behaviours when in close proximity to each other. However, their locomotion is not fully understood when coupled mechanically and hydrodynamically. In this study, we develop hydrodynamic models to investigate the locomotion of paired spermatozoa, predicting the fine structure of their swimming. Experimentally, sperm pairs are observed to transition between different modes of flagellar synchronisation: in-phase, anti-phase and lagged synchronisation. Using our models, we assess their swimming performances in these synchronisation modes in terms of average swimming speed, average power consumption, and swimming efficiency. The swimming performances of paired spermatozoa are shown to depend on their flagellar phase lag, flagellar waveforms, and the mechanical coupling between their heads.

AB - Microorganisms, such as spermatozoa, exhibit rich behaviours when in close proximity to each other. However, their locomotion is not fully understood when coupled mechanically and hydrodynamically. In this study, we develop hydrodynamic models to investigate the locomotion of paired spermatozoa, predicting the fine structure of their swimming. Experimentally, sperm pairs are observed to transition between different modes of flagellar synchronisation: in-phase, anti-phase and lagged synchronisation. Using our models, we assess their swimming performances in these synchronisation modes in terms of average swimming speed, average power consumption, and swimming efficiency. The swimming performances of paired spermatozoa are shown to depend on their flagellar phase lag, flagellar waveforms, and the mechanical coupling between their heads.

KW - micro-organism dynamics

KW - propulsion

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DO - 10.1017/jfm.2025.79

M3 - Article

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SN - 0022-1120

VL - 1007

JO - Journal of fluid mechanics

JF - Journal of fluid mechanics

M1 - A43

ER -

Locomotion of paired spermatozoa during flagellar synchronisation

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