Rapid bacterial motility monitoring using inexpensive 3D-printed OpenFlexure microscopy allows microfluidic antibiotic susceptibility testing
Rapid bacterial motility monitoring using inexpensive 3D-printed OpenFlexure microscopy allows microfluidic antibiotic susceptibility testing
Antibiotic susceptibility testing is vital to tackle the emergence and spread of antimicrobial resistance. Inexpensive digital CMOS cameras can be converted into portable digital microscopes using 3D printed x-y-z stages. Microscopic examination of bacterial motility can rapidly detect the response of microbes to antibiotics to determine susceptibility. Here, we present a new simple microdevice-miniature microscope cell measurement system for multiplexed antibiotic susceptibility testing. The microdevice is made using melt-extruded plastic film strips containing ten parallel 0.2 mm diameter microcapillaries. Two different antibiotics, ceftazidime and gentamicin, were prepared in Mueller-Hinton agar (0.4%) to produce an antibiotic-loaded microdevice for simple sample addition. This combination was selected to closely match current standard methods for both antibiotic susceptibility testing and motility testing. Use of low agar concentration permits observation of motile bacteria responding to antibiotic exposure as they enter capillaries. This device fits onto the OpenFlexure 3D-printed digital microscope using a Raspberry Pi computer and v2 camera, avoiding need for expensive laboratory microscopes. This inexpensive and portable digital microscope platform had sufficient magnification to detect motile bacteria, yet wide enough field of view to monitor bacteria behavior as they entered antibiotic-loaded microcapillaries. The image quality was sufficient to detect how bacterial motility was inhibited by different concentrations of antibiotic. We conclude that a 3D-printed Raspberry Pi-based microscope combined with disposable microfluidic test strips permit rapid, easy-to-use bacterial motility detection, with potential for aiding detection of antibiotic resistance.
Diep, Tai The
e1684015-0e0c-4a52-a0de-933de7647b53
Needs, Sarah Helen
24425556-99e3-4c46-995b-2381776a0a38
Bizley, Samuel
e2d03859-89ea-4a74-b8b0-b43c96e45d6f
Edwards, Alexander D.
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14 November 2022
Diep, Tai The
e1684015-0e0c-4a52-a0de-933de7647b53
Needs, Sarah Helen
24425556-99e3-4c46-995b-2381776a0a38
Bizley, Samuel
e2d03859-89ea-4a74-b8b0-b43c96e45d6f
Edwards, Alexander D.
bc3d9b93-a533-4144-937b-c673d0a28879
Diep, Tai The, Needs, Sarah Helen, Bizley, Samuel and Edwards, Alexander D.
(2022)
Rapid bacterial motility monitoring using inexpensive 3D-printed OpenFlexure microscopy allows microfluidic antibiotic susceptibility testing.
Micromachines, 13 (11).
(doi:10.3390/mi13111974).
Abstract
Antibiotic susceptibility testing is vital to tackle the emergence and spread of antimicrobial resistance. Inexpensive digital CMOS cameras can be converted into portable digital microscopes using 3D printed x-y-z stages. Microscopic examination of bacterial motility can rapidly detect the response of microbes to antibiotics to determine susceptibility. Here, we present a new simple microdevice-miniature microscope cell measurement system for multiplexed antibiotic susceptibility testing. The microdevice is made using melt-extruded plastic film strips containing ten parallel 0.2 mm diameter microcapillaries. Two different antibiotics, ceftazidime and gentamicin, were prepared in Mueller-Hinton agar (0.4%) to produce an antibiotic-loaded microdevice for simple sample addition. This combination was selected to closely match current standard methods for both antibiotic susceptibility testing and motility testing. Use of low agar concentration permits observation of motile bacteria responding to antibiotic exposure as they enter capillaries. This device fits onto the OpenFlexure 3D-printed digital microscope using a Raspberry Pi computer and v2 camera, avoiding need for expensive laboratory microscopes. This inexpensive and portable digital microscope platform had sufficient magnification to detect motile bacteria, yet wide enough field of view to monitor bacteria behavior as they entered antibiotic-loaded microcapillaries. The image quality was sufficient to detect how bacterial motility was inhibited by different concentrations of antibiotic. We conclude that a 3D-printed Raspberry Pi-based microscope combined with disposable microfluidic test strips permit rapid, easy-to-use bacterial motility detection, with potential for aiding detection of antibiotic resistance.
Text
micromachines-13-01974-v2
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Accepted/In Press date: 12 November 2022
Published date: 14 November 2022
Identifiers
Local EPrints ID: 495094
URI: http://eprints.soton.ac.uk/id/eprint/495094
ISSN: 2072-666X
PURE UUID: 1b6d87ed-91ab-4e0e-bbda-b2d3c865c615
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Date deposited: 29 Oct 2024 17:37
Last modified: 30 Oct 2024 03:06
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Author:
Tai The Diep
Author:
Sarah Helen Needs
Author:
Samuel Bizley
Author:
Alexander D. Edwards
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