Motion history images: a new method for tracking microswimmers in 3D

Riekeles, Max; Albalkhi, Hadi; Dubay, Megan Marie; Nadeau, Jay; Lindensmith, Christian A.

doi:10.3389/fimag.2024.1393314

Front. Imaging

2024

DOI: 10.3389/fimag.2024.1393314

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Motion history images: a new method for tracking microswimmers in 3D

Max Riekeles,

Hadi Albalkhi,

Megan Marie Dubay

et al.

Abstract: Quantitative tracking of rapidly moving micron-scale objects remains an elusive challenge in microscopy due to low signal-to-noise. This paper describes a novel method for tracking micron-sized motile organisms in off-axis Digital Holographic Microscope (DHM) raw holograms and/or reconstructions. We begin by processing the microscopic images with the previously reported Holographic Examination for Life-like Motility (HELM) software, which provides a variety of tracking outputs including motion history images (… Show more

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References 34 publications

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Viability and Motility of Escherichia coli Under Elevated Martian Salt Stresses

Riekeles,

Santos,

Youssef

et al. 2024

Life

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This study investigates the effects of three Martian-relevant salts—sodium chlorate, sodium perchlorate, and sodium chloride—on the viability and motility of Escherichia coli, a model organism for understanding microbial responses to environmental stress. These salts are abundant on Mars and play a crucial role in forming brines, one of the few sources of stable liquid water on the planet. We analyze the survivability under different salt concentrations using colony plating. Additionally, we perform a semi-automated motility analysis, analyzing microbial speeds and motility patterns. Our results show that sodium perchlorate is the most toxic, followed by sodium chlorate, with sodium chloride being the least harmful. Both survivability and motility are affected by salt concentration and exposure time. Notably, we observe a short-lived increase in motility at certain concentrations, particularly under sodium chlorate and sodium perchlorate stress, despite rapid declines in cell viability, suggesting a stress response mechanism. Given that motility might enhance an organism’s ability to navigate harsh and variable environments, it holds promise as a key biosignature in the search for life on Mars.

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Viability and Motility of Escherichia coli Under Elevated Martian Salt Stresses

Riekeles,

Santos,

Youssef

et al. 2024

Life

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Motion history images: a new method for tracking microswimmers in 3D

Cited by 1 publication

References 34 publications

Viability and Motility of Escherichia coli Under Elevated Martian Salt Stresses

Viability and Motility of Escherichia coli Under Elevated Martian Salt Stresses

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