Label-free analysis of bacterial growth and lysis at the single-cell level using droplet microfluidics and object detection-oriented deep learning
Label-free analysis of bacterial growth and lysis at the single-cell level using droplet microfluidics and object detection-oriented deep learning
Bacteria identification and counting at the small population scale is important to many applications in the food safety industry, the diagnostics of infectious diseases and the study and discovery of novel antimicrobial compounds. There is still a lack of easy to implement, fast and accurate methods to count populations of motile cells at the single-cell level. Here, we report a label-free method to count and localize bacterial cells freely swimming in microfluidic anchored picolitre droplets. We used the object detection oriented YOLOv4 deep learning framework for cell detection from bright-field images obtained with an automated Z-stack setup. The neural network was trained to recognize Escherichia coli cell morphology with an average precision of approximately 84%. This allowed us to accurately identify individual cell division events, enabling the study of stochastic bacterial growth starting from initial populations as low as one cell. This work also demonstrates the ability to study single cell lysis in the presence of T7 lytic bacterial viruses (phages). The high precision in cell numbers facilitated the visualization of bacteria-phage interactions over timescale of hours, paving the way towards deciphering phage life cycles in confined environments.
1258155
Tiwari, Anuj
81d923e7-f8cf-4d73-9845-7549d554fba6
Nikolic, Nela
88a8f576-d9e2-4eb6-9219-39b7065963d3
Anagnostidis, Vasileios
6901485e-ac71-4cfe-8e84-ea6f7ff94ce0
Gielen, Fabrice
c77341af-6e84-468f-a89e-0dcda0a75139
5 December 2023
Tiwari, Anuj
81d923e7-f8cf-4d73-9845-7549d554fba6
Nikolic, Nela
88a8f576-d9e2-4eb6-9219-39b7065963d3
Anagnostidis, Vasileios
6901485e-ac71-4cfe-8e84-ea6f7ff94ce0
Gielen, Fabrice
c77341af-6e84-468f-a89e-0dcda0a75139
Tiwari, Anuj, Nikolic, Nela, Anagnostidis, Vasileios and Gielen, Fabrice
(2023)
Label-free analysis of bacterial growth and lysis at the single-cell level using droplet microfluidics and object detection-oriented deep learning.
Frontiers in Lab on a Chip Technologies, 2, .
(doi:10.3389/frlct.2023.1258155).
Abstract
Bacteria identification and counting at the small population scale is important to many applications in the food safety industry, the diagnostics of infectious diseases and the study and discovery of novel antimicrobial compounds. There is still a lack of easy to implement, fast and accurate methods to count populations of motile cells at the single-cell level. Here, we report a label-free method to count and localize bacterial cells freely swimming in microfluidic anchored picolitre droplets. We used the object detection oriented YOLOv4 deep learning framework for cell detection from bright-field images obtained with an automated Z-stack setup. The neural network was trained to recognize Escherichia coli cell morphology with an average precision of approximately 84%. This allowed us to accurately identify individual cell division events, enabling the study of stochastic bacterial growth starting from initial populations as low as one cell. This work also demonstrates the ability to study single cell lysis in the presence of T7 lytic bacterial viruses (phages). The high precision in cell numbers facilitated the visualization of bacteria-phage interactions over timescale of hours, paving the way towards deciphering phage life cycles in confined environments.
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frlct-02-1258155
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Accepted/In Press date: 30 October 2023
Published date: 5 December 2023
Additional Information:
The author(s) declare financial support was received for the research, authorship, and/or publication of this article. This work was supported by BBSRC grant BB/T011777/1 and BBSRC/NC3R grant (NC/X002187/1) to FG, the Wellcome Trust Institutional Strategic Support Funding (WT105618MA) Research Restart Award and Pump-Priming Initiative to NN. This work was also supported by the Biotechnology and Biological Sciences Research Council-funded South-West Biosciences Doctoral Training Partnership (training grant reference 2578821).
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Local EPrints ID: 487937
URI: http://eprints.soton.ac.uk/id/eprint/487937
PURE UUID: 0394e4aa-151e-4b08-9b26-fb990198f12f
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Date deposited: 11 Mar 2024 17:36
Last modified: 18 Mar 2024 04:18
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Author:
Anuj Tiwari
Author:
Nela Nikolic
Author:
Vasileios Anagnostidis
Author:
Fabrice Gielen
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