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Optimization and fabrication of multi-level microchannels for long-term imaging of bacterial growth and expansion

Optimization and fabrication of multi-level microchannels for long-term imaging of bacterial growth and expansion
Optimization and fabrication of multi-level microchannels for long-term imaging of bacterial growth and expansion
Bacteria are unicellular organisms whose length is usually around a few micrometers. Advances in microfabrication techniques have enabled the design and implementation of microdevices to confine and observe bacterial colony growth. Microstructures hosting the bacteria and microchannels for nutrient perfusion usually require separate microfabrication procedures due to different feature size requirements. This fact increases the complexity of device integration and assembly process. Furthermore, long-term imaging of bacterial dynamics over tens of hours requires stability in the microscope focusing mechanism to ensure less than one-micron drift in the focal axis. In this work, we design and fabricate an integrated multi-level, hydrodynamically-optimized microfluidic chip to study long-term Escherichia coli population dynamics in confined microchannels. Reliable long-term microscopy imaging and analysis has been limited by focus drifting and ghost effect, probably caused by the shear viscosity changes of aging microscopy immersion oil. By selecting a microscopy immersion oil with the most stable viscosity, we demonstrate successful captures of focally stable time-lapse bacterial images for ≥72 h. Our fabrication and imaging methodology should be applicable to other single-cell studies requiring long-term imaging.
2072-666X
Tsai, Hsieh-Fu
6c78a5bc-fe59-48f2-bbd7-6485375b0a4c
Carlson, Daniel W.
c0f88797-732c-46ef-8e74-a5186d4733bf
Koldaeva, Anzhelika
49b6cae7-a1df-4ab5-8690-1eeb4773589d
Pigolotti, Simone
03519424-59e8-4e70-9d29-4e24f4500f89
Shen, Amy Q.
f04513a5-fedd-4759-958a-674855da2600
Tsai, Hsieh-Fu
6c78a5bc-fe59-48f2-bbd7-6485375b0a4c
Carlson, Daniel W.
c0f88797-732c-46ef-8e74-a5186d4733bf
Koldaeva, Anzhelika
49b6cae7-a1df-4ab5-8690-1eeb4773589d
Pigolotti, Simone
03519424-59e8-4e70-9d29-4e24f4500f89
Shen, Amy Q.
f04513a5-fedd-4759-958a-674855da2600

Tsai, Hsieh-Fu, Carlson, Daniel W., Koldaeva, Anzhelika, Pigolotti, Simone and Shen, Amy Q. (2022) Optimization and fabrication of multi-level microchannels for long-term imaging of bacterial growth and expansion. Micromachines, 13 (4). (doi:10.3390/mi13040576).

Record type: Article

Abstract

Bacteria are unicellular organisms whose length is usually around a few micrometers. Advances in microfabrication techniques have enabled the design and implementation of microdevices to confine and observe bacterial colony growth. Microstructures hosting the bacteria and microchannels for nutrient perfusion usually require separate microfabrication procedures due to different feature size requirements. This fact increases the complexity of device integration and assembly process. Furthermore, long-term imaging of bacterial dynamics over tens of hours requires stability in the microscope focusing mechanism to ensure less than one-micron drift in the focal axis. In this work, we design and fabricate an integrated multi-level, hydrodynamically-optimized microfluidic chip to study long-term Escherichia coli population dynamics in confined microchannels. Reliable long-term microscopy imaging and analysis has been limited by focus drifting and ghost effect, probably caused by the shear viscosity changes of aging microscopy immersion oil. By selecting a microscopy immersion oil with the most stable viscosity, we demonstrate successful captures of focally stable time-lapse bacterial images for ≥72 h. Our fabrication and imaging methodology should be applicable to other single-cell studies requiring long-term imaging.

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Published date: 6 April 2022

Identifiers

Local EPrints ID: 507351
URI: http://eprints.soton.ac.uk/id/eprint/507351
DOI: doi:10.3390/mi13040576
ISSN: 2072-666X
PURE UUID: 14487bac-6070-45d5-8f0c-4229829a3549
ORCID for Daniel W. Carlson: ORCID iD orcid.org/0000-0002-0171-1934

Catalogue record

Date deposited: 04 Dec 2025 18:01
Last modified: 05 Dec 2025 03:03

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Contributors

Author: Hsieh-Fu Tsai
Author: Daniel W. Carlson ORCID iD
Author: Anzhelika Koldaeva
Author: Simone Pigolotti
Author: Amy Q. Shen

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