The Field Guide to 3D Printing in Microscopy

Rosario, Mario Del; Heil, Hannah S.; Mendes, Afonso; Saggiomo, Vittorio; Henriques, Ricardo

doi:10.20944/preprints202105.0352.v1

Cited by 6 publications

(8 citation statements)

References 146 publications

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“…Two scientific fields have greatly benefited from the advent of 3D printing and the possibility of rapid prototyping directly in the laboratory: microfluidics [ 23,24 ] and microscopy. [ 25 ]…”

Section: Phase Two: Designingmentioning

confidence: 99%

A 3D Printer in the Lab: Not Only a Toy

Saggiomo

2022

Advanced Science

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Although 3D printers are becoming more common in households, they are still under‐represented in many laboratories worldwide and regarded as toys rather than as laboratory equipment. This short review wants to change this conservative point of view. This mini‐review focuses on fused deposition modeling printers and what happens after acquiring your first 3D printer. In short, these printers melt plastic filament and deposit it layer by layer to create the final object. They are getting cheaper and easier to use, and nowadays it is not difficult to find good 3D printers for less than €500. At such a price, a 3D printer is one, if not the most, versatile piece of equipment you can have in a laboratory.

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Section: Phase Two: Designingmentioning

confidence: 99%

A 3D Printer in the Lab: Not Only a Toy

Saggiomo

2022

Advanced Science

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“…[19] The increasing complexity and associated costs of experiments, due to the increased use of laboratory equipment, as well as the knowledge required to properly operate all the necessary instruments, make high-throughput research very exclusive. [20,21] In turn, it is particularly challenging to train students to use such methods. [22] Our aim in this work is to prove the principle of lab automation using open, accessible tools, with the ultimate goal of making this technology more widespread and easier to use.…”

Section: Introductionmentioning

confidence: 99%

“…These projects have all been replicated by the growing community of microscopy users. For a great overview of the subject, please refer to Rosario et al [21] In most cases, commercial devices lack open hardware or software interfaces for customization or automation, making it difficult or impossible to use them outside of the intended application for the devices. The Opentrons OT-2 pipetting robot [6,28] which we use in this manuscript is an example of commercially produced open-source hardware.…”

Section: Introductionmentioning

confidence: 99%

An Open‐Source Modular Framework for Automated Pipetting and Imaging Applications

et al. 2021

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The number of samples in biological experiments is continuously increasing, but complex protocols and human error in many cases lead to suboptimal data quality and hence difficulties in reproducing scientific findings. Laboratory automation can alleviate many of these problems by precisely reproducing machine‐readable protocols. These instruments generally require high up‐front investments, and due to the lack of open application programming interfaces (APIs), they are notoriously difficult for scientists to customize and control outside of the vendor‐supplied software. Here, automated, high‐throughput experiments are demonstrated for interdisciplinary research in life science that can be replicated on a modest budget, using open tools to ensure reproducibility by combining the tools OpenFlexure, Opentrons, ImJoy, and UC2. This automated sample preparation and imaging pipeline can easily be replicated and established in many laboratories as well as in educational contexts through easy‐to‐understand algorithms and easy‐to‐build microscopes. Additionally, the creation of feedback loops, with later pipetting or imaging steps depending on the analysis of previously acquired images, enables the realization of fully autonomous “smart” microscopy experiments. All documents and source files are publicly available to prove the concept of smart lab automation using inexpensive, open tools. It is believed this democratizes access to the power and repeatability of automated experiments.

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“…The increasing complexity of experiments due to technologization, the associated cost of laboratory equipment, and the knowledge required to properly operate all the required instruments make highthroughput research very exclusive. 18,19 In turn, it is particularly challenging to train students to use such methods. 20 In the past, much open-source software and, more recently, open hardware projects have shown that by creating a community of developers and allowing them to develop the projects together, a high level of professionalism and usability is created, with the help being offered free of charge.…”

Section: Introductionmentioning

confidence: 99%

“…For a great overview of the subject, please refer to. 19 In most cases, commercial devices lack open hardware or software interfaces for customization or automation, making it difficult or impossible to use them outside of the intended application for the devices, e.g., within a self-designed biological protocol. The Opentrons OT-2 pipetting robot 6,26 which we use in this manuscript is an example of commercially produced open-source hardware.…”

Section: Introductionmentioning

confidence: 99%

An Open-Source Modular Framework for Automated Pipetting and Imaging Applications

Ouyang

Bowman

Wang

et al. 2021

Preprint

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The number of samples in biological experiments are continuously increasing, but complex protocols and human experimentation in many cases lead to suboptimal data quality and hence difficulties in reproducing scientific findings. Laboratory automation can alleviate many of these problems by precisely reproducing machine-readable protocols. These instruments generally require high up-front investments and due to lack of open APIs they are notoriously difficult for scientists to customize and control outside of the vendor-supplied software. Here, we demonstrate automated, high-throughput experiments for interdisciplinary research in life science that can be replicated on a modest budget, using open tools to ensure reproducibility by combining the tools Openflexure, Opentrons, ImJoy and UC2. Our automated sample preparation and imaging pipeline can easily be replicated and established in many laboratories as well as in educational contexts through easy-to-understand algorithms and easy-to-build microscopes. Additionally, the creation of feedback loops, with later pipetting or imaging steps depending on analysis of previously acquired images, enables the realization of smart microscopy experiments, featuring completely autonomously performed experiments. All documents and source-files are publicly available (https://beniroquai.github.io/Hi2) to prove the concept of smart lab automation using inexpensive, open tools. We believe this democratizes access to the power and repeatability of automated experiments.

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The Field Guide to 3D Printing in Microscopy

Cited by 6 publications

References 146 publications

A 3D Printer in the Lab: Not Only a Toy

A 3D Printer in the Lab: Not Only a Toy

An Open‐Source Modular Framework for Automated Pipetting and Imaging Applications

An Open-Source Modular Framework for Automated Pipetting and Imaging Applications

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