The pumping lid: investigating multi-material 3D printing for equipment-free, programmable generation of positive and negative pressures for microfluidic applications
Abstract
Equipment-free pumping is a challenging problem and an active area of research in microfluidics, with applications for both laboratory and limited-resource settings. This paper describes the pumping lid method, a strategy to achieve equipment-free pumping by controlled generation of pressure. Pressure was generated using portable, lightweight, and disposable parts that can be integrated with existing microfluidic devices to simplify workflow and eliminate the need for pumping equipment. The development of this method was enabled by multi-material 3D printing, which allows fast prototyping, including composite parts that combine materials with different mechanical properties (e.g. both rigid and elastic materials in the same part). The first type of pumping lid we describe was used to produce predictable positive or negative pressures via controlled compression or expansion of gases. A model was developed to describe the pressures and flow rates generated with this approach and it was validated experimentally. Pressures were pre-programmed by the geometry of the parts and could be tuned further even while the experiment was in progress. Using multiple lids or a composite lid with different inlets enabled several solutions to be pumped independently in a single device. The second type of pumping lid, which relied on vapor–liquid equilibrium to generate pressure, was designed, modeled, and experimentally characterized. The pumping lid method was validated by controlling flow in different types of microfluidic applications, including the production of droplets, control of laminar flow profiles, and loading of SlipChip devices. We believe that applying the pumping lid methodology to existing microfluidic devices will enhance their use as portable diagnostic tools in limited resource settings as well as accelerate adoption of microfluidics in laboratories.
Additional Information
© 2014 Royal Society of Chemistry. Received 5th August 2014; accepted 5th September 2014. First published online 18 Sep 2014. This work was funded in part by DARPA Cooperative Agreement HR0011-11-2-0006 and National Institutes of Health NRSA training grant 5T32GM07616NSF (to D.A.S.). This material is also based upon work supported by a National Science Foundation Graduate Research Fellowship under grant no. DGE‐1144469 (to D.V.Z.). This paper does not necessarily reflect the position or policy of the U.S. government or these agencies, and no official endorsement should be inferred. We wish to thank Mikhail Karymov for preliminary experiments, Roberta Poceviciute for help with the theoretical analysis, and Natasha Shelby for contributions to writing and editing this manuscript. We also wish to thank the 6 year-old volunteer for performing the demonstrations shown in Fig. 6. Disclosure: R.F.I. and L.L. have a financial interest in SlipChip Corp.Attached Files
Published - c4lc00910j.pdf
Supplemental Material - c4lc00910j1.mp4
Supplemental Material - c4lc00910j2.pdf
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Additional details
- Eprint ID
- 50021
- Resolver ID
- CaltechAUTHORS:20140925-085504154
- PMCID
- PMC10773560
- HR0011-11-2-0006
- Defense Advanced Research Projects Agency (DARPA)
- 5T32GM07616NSF
- NIH
- DGE‐1144469
- NSF Graduate Research Fellowship
- Created
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2014-09-25Created from EPrint's datestamp field
- Updated
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2021-11-10Created from EPrint's last_modified field