Issue 38, 2022

Tracking Janus microswimmers in 3D with machine learning

Abstract

Advancements in artificial active matter systems heavily rely on our ability to characterise their motion. Yet, the most widely used tool to analyse the latter is standard wide-field microscopy, which is largely limited to the study of two-dimensional motion. In contrast, real-world applications often require the navigation of complex three-dimensional environments. Here, we present a Machine Learning (ML) approach to track Janus microswimmers in three dimensions, using Z-stacks as labelled training data. We demonstrate several examples of ML algorithms using freely available and well-documented software, and find that an ensemble Decision Tree-based model (Extremely Randomised Decision Trees) performs the best at tracking the particles over a volume spanning more than 40 μm. With this model, we are able to localise Janus particles with a significant optical asymmetry from standard wide-field microscopy images, bypassing the need for specialised equipment and expertise such as that required for digital holographic microscopy. We expect that ML algorithms will become increasingly prevalent by necessity in the study of active matter systems, and encourage experimentalists to take advantage of this powerful tool to address the various challenges within the field.

Graphical abstract: Tracking Janus microswimmers in 3D with machine learning

Supplementary files

Article information

Article type
Paper
Submitted
11 Jul 2022
Accepted
04 Sep 2022
First published
05 Sep 2022
This article is Open Access
Creative Commons BY-NC license

Soft Matter, 2022,18, 7291-7300

Tracking Janus microswimmers in 3D with machine learning

M. R. Bailey, F. Grillo and L. Isa, Soft Matter, 2022, 18, 7291 DOI: 10.1039/D2SM00930G

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