PiRamid: a compact Raspberry Pi imaging box to automate small-scale time-lapse digital analysis, suitable for laboratory and field use
PiRamid: a compact Raspberry Pi imaging box to automate small-scale time-lapse digital analysis, suitable for laboratory and field use
Digital imaging permits the quantitation of many experiments, such as microbiological growth assays, but laboratory digital imaging systems can be expensive and too specialised. The Raspberry Pi camera platform makes automated, controlled imaging affordable with accessible customisation. When combined with open source software and open-source 3D printed hardware, the control over image quality and capture of this platform permits the rapid development of novel instrumentation. Here we present “PiRamid”, a compact, portable, and inexpensive enclosure for autonomous imaging both in the laboratory and in the field. The modular three-piece 3D printed design makes it easy to incorporate different camera systems or lighting configurations (e.g., single wavelength LED for fluorescence). The enclosed design allows complete control of illumination unlike a conventional digital camera or smartphone, on a tripod or handheld, under ambient lighting. The stackable design permits rapid sample addition or camera focus adjustment, with a corresponding change in magnification and resolution. The entire unit is small enough to fit within a microbiological incubator, and cheap enough (∼£100) to scale out for larger parallel experiments. Simply, Python scripts fully automate illumination and image capture for small-scale experiments with an ∼110×85 mm area at 70–90 µm resolution. We demonstrate the versatility of PiRamid by capturing time-resolved, quantitative image data for a wide range of assays. Bacterial growth kinetics was captured for conventional microbiology (agar Petri dishes), 3D printed custom microbiology labware and microfluidic microbiology. To illustrate application beyond microbiology, we demonstrate time-lapse imaging of crystal growth and degradation of salad leaves. Minor modifications permit epi-illumination by addition of a LED ring to the camera module. We conclude that PiRamid permits inexpensive digital capture and quantitation of a wide range of experiments by time-lapse imaging to simplify both laboratory and field imaging.
Long, Matthew Michael
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Diep, Tai The
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Needs, Sarah Helen
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Ross, Marta Joan
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Edwards, Alexander Daniel
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Long, Matthew Michael
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Diep, Tai The
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Needs, Sarah Helen
24425556-99e3-4c46-995b-2381776a0a38
Ross, Marta Joan
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Edwards, Alexander Daniel
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Long, Matthew Michael, Diep, Tai The, Needs, Sarah Helen, Ross, Marta Joan and Edwards, Alexander Daniel
(2022)
PiRamid: a compact Raspberry Pi imaging box to automate small-scale time-lapse digital analysis, suitable for laboratory and field use.
HardwareX, 12.
(doi:10.1016/J.OHX.2022.E00377).
Abstract
Digital imaging permits the quantitation of many experiments, such as microbiological growth assays, but laboratory digital imaging systems can be expensive and too specialised. The Raspberry Pi camera platform makes automated, controlled imaging affordable with accessible customisation. When combined with open source software and open-source 3D printed hardware, the control over image quality and capture of this platform permits the rapid development of novel instrumentation. Here we present “PiRamid”, a compact, portable, and inexpensive enclosure for autonomous imaging both in the laboratory and in the field. The modular three-piece 3D printed design makes it easy to incorporate different camera systems or lighting configurations (e.g., single wavelength LED for fluorescence). The enclosed design allows complete control of illumination unlike a conventional digital camera or smartphone, on a tripod or handheld, under ambient lighting. The stackable design permits rapid sample addition or camera focus adjustment, with a corresponding change in magnification and resolution. The entire unit is small enough to fit within a microbiological incubator, and cheap enough (∼£100) to scale out for larger parallel experiments. Simply, Python scripts fully automate illumination and image capture for small-scale experiments with an ∼110×85 mm area at 70–90 µm resolution. We demonstrate the versatility of PiRamid by capturing time-resolved, quantitative image data for a wide range of assays. Bacterial growth kinetics was captured for conventional microbiology (agar Petri dishes), 3D printed custom microbiology labware and microfluidic microbiology. To illustrate application beyond microbiology, we demonstrate time-lapse imaging of crystal growth and degradation of salad leaves. Minor modifications permit epi-illumination by addition of a LED ring to the camera module. We conclude that PiRamid permits inexpensive digital capture and quantitation of a wide range of experiments by time-lapse imaging to simplify both laboratory and field imaging.
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PIIS2468067222001225
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Accepted/In Press date: 12 November 2022
e-pub ahead of print date: 23 November 2022
Identifiers
Local EPrints ID: 495107
URI: http://eprints.soton.ac.uk/id/eprint/495107
ISSN: 2468-0672
PURE UUID: 2d661851-cb87-424e-a0a9-84c948110c26
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Date deposited: 29 Oct 2024 17:43
Last modified: 30 Oct 2024 03:06
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Author:
Matthew Michael Long
Author:
Tai The Diep
Author:
Sarah Helen Needs
Author:
Marta Joan Ross
Author:
Alexander Daniel Edwards
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