This GitHub repository is an in-progress collection of Open Source Hardware instrumentation for microfluidics and ultra-high troughput lifescience experimentation research. This is a community driven effort and you are invited to contribute thoughts, content, comments and help testing the instrumentation!
This projekt is run as part of my current Fellowship Freies Wissen (translates to Open Knowledge), here is the project description on the corresponding Wikiversity page and see the file Roadmap.md as well as the intermediate report.
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A review outline that collects information on the openess of the research field, its instrumentation and reagents. Please comment by submitting issues on GitHub or contact me directly if you want to be part of the more concentrated writing effort: Tobias.Wenzel /at/ embl.de
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A list of microfluidics relevant Open Source Harwdare instrumentation, connected to the practical aim of testing the documentations by reading them carefully, by building the instrumentation in some cases (remotely and Heidelberg based workshop in early 2019) and further by testing, comparing and calibrating the equipement. Everyone is welcome to contribute. Please contact me directly (Tobias.Wenzel /at/ embl.de) if you need financial help with hardware parts in oder to test the documentations and redocument them on DocuBricks to create more accessible, open hardware standard documentations.
Increasing openess can be acheived in many different ways, such as increased accessibility of techniques or results to a professional or general audience, greater ease of use, increased mobility of researchers of different seniority, discipines or ethnicity into the field. One aspect that enjoys recent popularity in microfluidic and bioprocess technologies is the "biohacker"or Do-It-Yourself (DIY) biology movement. The later includes self-made and low-cost research instrumentation. Such advances in openess greatly improve the accessibility of microfluidic and related technology to lay people and have been reviewed recently [akerspaces." Trends in Biotechnology (February 3, 2017). https://doi.org/10.1016/j.tibtech.2017.01.001]. The open source hardware originating from this context does usually not, however, fulfill key application relevant criteria such as basic safety mechanisms (e.g. dremel fuge), bencharking calibration assessment (e.g. XXX), and documentation best practices as reccomended by the GOSH community [e.g. https://www.docubricks.com/best-practise-guide.jsp] or the Journal of Open Hardware, OSWA, etc. For the above reasond of focus and qality management, here we focus on hardware and manufacturing related aspects of microfluidic and related technology for professional (in particular academic) applications. In particular we probe
(I) the use of open platforms and software.
(II) digitalisation and use/challenges of digital manufacturing
(III) identification of potentially valualble resources for microfluidic research drawing on digital manufacturing, open source and publis resources.
- high quality small-scale fluidic chip manufacturing techniques
- imaging of droplets (normal, fhigh-speed (e.g. stroboscopic+software), fluorescence)
- sorting of droplets (hardware-fast-processing, software, instructions)
- pressure control
- simlation tools
- open reagents
Free and Open Source Hardware resources of interest for testing and further development - selected promising resources
Any contribution and participation welcome! I am happy to connect and perhaps even help with resources, parts and potential parts-funding! Comment here, via issues, or email me.
After looking at the details of the project, this seems like a fantastic piece of hardware and documentation. We will definitely try to build it and have already ordered all parts. Nice small and low-cost solutions for pressure controll. Parts are being purchased at the moment. Please look into the respective sub-repository:
https://github.com/MakerTobey/OpenMicrofluidics/tree/master/Minidrop%20build%20and%20test
https://metafluidics.org/devices/minidrops/ https://www.nature.com/articles/s41467-017-02659-x#Sec9
This is an active contsturction project! For files and progress, please look into the respective folder in this repository: https://github.com/MakerTobey/OpenMicrofluidics/tree/master/Open%20FADS
FACS (Fluorescence Activated Cell Sorting) equivalent sorting of droplets for directed evolution and many other essays is a key method in microfluidics that only few labs master. One of the reasons is that few instructions are available (but they do exsist! See Christoph Merten in Nature Methods), and equipemnt is complex, propriatory and very expensive. A common work station for droplet sorting usually costs ca. 100.000 Euro. Now, an open source version (no propriatory sorware and harware lock-in, modifiable, modular and extensible) comes within reach!
http://www.appropedia.org/Open-source_syringe_pump We have built two, but will further upgrade and test.
http://www.appropedia.org/Lynch_open_source_syringe_pump_modifications https://www.sciencedirect.com/science/article/pii/S2468067218300269
We are building and testing some of this hardware! Please look into the respective project subfolder: https://github.com/MakerTobey/OpenMicrofluidics/tree/master/pressure%20control%20bild%20and%20test
My own project to build an ardunino based 2-channel pressure controll (pressure derived from a compressor), to be extended and tested: https://www.docubricks.com/viewer.jsp?id=6067044959053384704 Also explore our seperate GitHub repository: https://github.com/MakerTobey/uFluid
This project looks similar and deserves further attention: https://hackaday.io/project/148274-electronic-pressure-regulator, https://github.com/watsaig/ufcs-pc
A useful manifold for quake-style valves, already build and soon to be tested: https://github.com/GNHua/valve-control
Another useful manifold for quake-style valves, to be tested soon: https://metafluidics.org/devices/32-channel-controller/ Is this documentation incomplete?
In this project and with colleagues, we are following up on thiese hardware pieces. The Minidrop station includes another curstom pressure controll implementation.
OpenDrop http://www.gaudi.ch/GaudiLabs/?page_id=392
And Dropbot http://microfluidics.utoronto.ca/dropbot/
Open Flexure Microscope https://aip.scitation.org/doi/10.1063/1.4941068 https://www.docubricks.com/viewer.jsp?id=6067044959053384704 with objective: https://github.com/rwb27/openflexure_microscope with motorisation: https://github.com/rwb27/openflexure_nano_motor_controller We are currently waiting for the new release (large, with automation and objective) to build one.
FlyPi: https://open-labware.net/projects/flypi/ https://journals.plos.org/plosbiology/article?id=10.1371/journal.pbio.2002702
No microfluidics related fast imaging open hardware projects are konwn to us so far! Please let me know if you are aware of a resource. Fast-responding cameras would be great or stroboscopic illumination for droplet microfluidics.
I believe that stroboscopic imaging has already been build by many labs. Who would be interested to publish the designs openly?
Paper references of possible interest: https://www.hindawi.com/journals/jamc/2009/198732/ https://aapt.scitation.org/doi/abs/10.1119/1.4863916 https://www.mdpi.com/2072-666X/8/12/351 https://www.future-science.com/doi/abs/10.2144/000112220 https://www.sciencedirect.com/science/article/pii/S0165027012003846 https://media.proquest.com/media/pq/classic/doc/4322030507/fmt/ai/rep/NPDF?_s=EUAbzVz%2B%2FEKGyiix9oguFSmtgAU%3D
Maybe: https://pdfs.semanticscholar.org/63f0/b73d48380f3d5d3614e0fe12ae55adaeb1dd.pdf https://www.spiedigitallibrary.org/conference-proceedings-of-spie/5145/0000/Simultaneous-mapping-of-phase-and-amplitude-of-MEMS-vibrations-by/10.1117/12.500138.short?SSO=1 https://scholar.google.de/scholar?hl=en&as_sdt=0%2C5&as_vis=1&q=stroboscopic%2Billumination%2Bmicroscope%2Barduino&btnG= https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0143547 https://pubs.acs.org/doi/abs/10.1021/ja074704l
Open Source imaging chips: https://wiki.apertus.org/index.php/Main_Page
Open Source imaging software: https://www.osapublishing.org/boe/abstract.cfm?uri=boe-1-2-385