Picroscope: low-cost system for simultaneous longitudinal biological imaging

Ly, Victoria T.; Baudin, Pierre V.; Pansodtee, Pattawong; Jung, Erik; Voitiuk, Kateryna; Rosen, Yohei M.; Willsey, Helen Rankin; Mantalas, Gary L.; Seiler, Spencer T.; Selberg, John; Cordero, Sergio; Ross, Jayden; Rolandi, Marco; Pollen, Alex A.; Nowakowski, Tomasz J.; Haussler, David; Mostajo-Radji, Mohammed A.; Salama, Sofie R.; Teodorescu, Mircea

doi:10.1038/s42003-021-02779-7

Cited by 28 publications

(22 citation statements)

References 75 publications

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“…An outline of existing tools that utilize the platform described in this paper. (Assay) shows the Picroscope Ly et al (2021); Baudin et al (2021) for microscopy, the Piphys Voitiuk et al (2021) for electrophysiology recording, and a fully automated auto-culture system for media recording and replacement. (Infrastructure) shows the primary suite of tools introduced in section 2.2, 2.4 and 2.5 in this paper.…”

Section: System Designmentioning

confidence: 99%

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Internet of Things Architecture for Cellular Biology

Parks

Voitiuk

Geng

et al. 2021

Preprint

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New cell culture techniques have led to complex tissue models in biological experiments. For example, 3-D cerebral organoids provide a more realistic model of the human cortical tissue. However, these cell culture experiments are restricted by high costs and limited labor. A massively scalable and cost efficient platform for tissue experiments would benefit genomics, neuroscience, and translational medicine by enabling advanced high throughput tissue screens. Cloud computing and the Internet of Things (IoT) provide new tools for managing multiple experiments in parallel that are remotely controlled through automation. We introduce a cloud-based IoT architecture that takes advantage of these tools to offer an environment where researchers can run thousands of cell culture experiments at once. This technology allows studies with cell cultures to be performed at scales far beyond a single lab setting, democratizing access to advanced tissue models and enabling new avenues of research.

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Section: System Designmentioning

confidence: 99%

“…(Analysis) demos some of the reports produced as a result of the workflows that run as post-processing jobs. (the “Picroscope” and “Piphys” figures are adapted from Ly et al (2021); Baudin et al (2021) and Voitiuk et al (2021))…”

Section: System Designmentioning

confidence: 99%

Internet of Things Architecture for Cellular Biology

Parks

Voitiuk

Geng

et al. 2021

Preprint

Self Cite

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“…Raspberry Pis can connect to a dedicated camera, and the picamera Python package allows for a high level of user control with regards to its settings and functionality [9]. Across a range of fields, various biological studies have used the Raspberry Pi as a camera device to monitor behavior, growth, and development of animals, plants, and bacteria [2,[10][11][12][13][14]. For instance, the Raspberry Pi was used to create "POLIR," an open-source, customizable system for high throughput analytical microbiology imaging, and "Picroscope" uses the Raspberry Pi for a microscope for simultaneous longitudinal imaging, with demonstrated applications in 2D and 3D cell/tissue cultures and whole organism imaging of frog and zebrafish development and planaria regeneration [10,14].…”

Section: Introductionmentioning

confidence: 99%

“…Across a range of fields, various biological studies have used the Raspberry Pi as a camera device to monitor behavior, growth, and development of animals, plants, and bacteria [2,[10][11][12][13][14]. For instance, the Raspberry Pi was used to create "POLIR," an open-source, customizable system for high throughput analytical microbiology imaging, and "Picroscope" uses the Raspberry Pi for a microscope for simultaneous longitudinal imaging, with demonstrated applications in 2D and 3D cell/tissue cultures and whole organism imaging of frog and zebrafish development and planaria regeneration [10,14]. However, researchers are often required to program their Raspberry Pis and create setups specifically for their studies (e.g.…”

Section: Introductionmentioning

confidence: 99%

PiSpy: An Affordable, Accessible, and Flexible Imaging Platform for the Automated Observation of Organismal Biology and Behavior

Morris

Kittredge

Casey

et al. 2022

Preprint

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A great deal of understanding can be gleaned from direct observation of organismal growth, development, and behavior. However, direct observation can be time consuming and influence the organism through unintentional stimuli. Additionally, video capturing equipment can often be prohibitively expensive, difficult to modify to one's specific needs, and may come with unnecessary features. Here, we describe the PiSpy, a low-cost, automated video acquisition platform that uses a Raspberry Pi computer and camera to record video or images at specified time intervals or when externally triggered. All settings and controls, such as programmable light cycling, are accessible to users with no programming experience through an easy-to-use graphical user interface. Importantly, the entire PiSpy system can be assembled for less than $100 using laser-cut and 3D-printed components. We demonstrate the broad applications and flexibility of the PiSpy across a range of model and non-model organisms. Designs, instructions, and code can be accessed through an online repository, where a global community of PiSpy users can also contribute their own unique customizations and help grow the community of open-source research solutions.

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“…Given the resolution and precision of 3D printing, as well as the inherent ability to customize, applications in microscopy are numerous to develop low cost specialized solutions [ 3 , 4 ] to open sourced projects that significantly lower the cost barrier to high performance microscopy, such as the OpenFlexure system [ 5 – 7 ]. 3D printing has been adopted successfully to create microscopy stage chambers for the study of model organisms in three and four dimensions [ 8 ].…”

Section: Introductionmentioning

confidence: 99%

Mod3D: A low-cost, flexible modular system of live-cell microscopy chambers and holders

et al. 2022

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Live-cell microscopy imaging typically involves the use of high-quality glass-bottom chambers that allow cell culture, gaseous buffer exchange and optical properties suitable for microscopy applications. However, commercial sources of these chambers can add significant annual costs to cell biology laboratories. Consumer products in three-dimensional printing technology, for both Filament Deposition Modeling (FDM) and Masked Stereo Lithography (MSLA), have resulted in more biomedical research labs adopting the use of these devices for prototyping and manufacturing of lab plastic-based items, but rarely consumables. Here we describe a modular, live-cell chamber with multiple design options that can be mixed per experiment. Single reusable carriers and the use of biodegradable plastics, in a hybrid of FDM and MSLA manufacturing methods, reduce plastic waste. The system is easy to adapt to bespoke designs, with concept-to-prototype in a single day, offers significant cost savings to the users over commercial sources, and no loss in dimensional quality or reliability.

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Picroscope: low-cost system for simultaneous longitudinal biological imaging

Cited by 28 publications

References 75 publications

Internet of Things Architecture for Cellular Biology

Internet of Things Architecture for Cellular Biology

PiSpy: An Affordable, Accessible, and Flexible Imaging Platform for the Automated Observation of Organismal Biology and Behavior

Mod3D: A low-cost, flexible modular system of live-cell microscopy chambers and holders

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