Microfluidics made easy: A robust low-cost constant pressure flow controller for engineers and cell biologists

Mavrogiannis, Nicholas; Ibo, Markela; Fu, Xiaotong; Crivellari, Francesca; Gagnon, Zachary

doi:10.1063/1.4950753

Cited by 52 publications

(40 citation statements)

References 20 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…It would also mean that we would need much higher pressures than recommended for the Duran pressure solvent reservoir . Inspired by the use of capillary resistors currently used in the field of microfluidics, we decided to control the hydraulic resistance of our pressure‐driven system and the flow rate by altering the pressure applied according to the Hagen–Poiseuille law [Equation ] which can also be simplified to Equation , where R h is the hydraulic resistance.

Q = \frac{Δ P π r^{4}}{8 μ L}

Δ P = Q R_{h}

…”

Section: Resultsmentioning

confidence: 99%

“…Based on this equation, we would need to know R h of the whole system were we to control the flow rate. However, if the R h of a capillary resistor is greater than that of the whole system, it can readily regulate the flow rate . As the flow system uses 1.0 mm ID tubing and a meso‐scale reactor in the use of the CDRs, we envisaged that addition of easily accessible HPLC PEEK tubing would allow us to develop a suitable set of capillary resistors that would offer sufficient resistance and also be compatible with organic solvents obviating the need for back pressure regulators.…”

Section: Resultsmentioning

confidence: 99%

See 1 more Smart Citation

Modular 3D Printed Compressed Air Driven Continuous‐Flow Systems for Chemical Synthesis

Penny¹,

Rao²,

Peniche

et al. 2019

Eur J Org Chem

View full text Add to dashboard Cite

In this present study, we describe the development of a low‐cost, small‐footprint and modular 3D printed continuous‐flow system that readily attaches to existing stirrer hotplates. Flow‐rates are controlled by compressed air that is typically present in all fume hoods, making it suitable for use by synthetic chemists. The length of the flow‐path and reaction residence time is regulated by control of the air‐flow and pressure and by addition of one or more 3D printed polypropylene (PP) circular disk reactors that were designed to fit a DrySyn Multi‐E base, which is found in most synthetic laboratories. The ease of use of the system, the facile control of flow‐rates and the solvent resistance of the PP reactors was demonstrated in a range of SNAr reactions to produce substituted ether derivatives highlighting the utility and modularity of the system.

show abstract

Q = \frac{Δ P π r^{4}}{8 μ L}

Δ P = Q R_{h}

…”

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Modular 3D Printed Compressed Air Driven Continuous‐Flow Systems for Chemical Synthesis

Penny¹,

Rao²,

Peniche

et al. 2019

Eur J Org Chem

View full text Add to dashboard Cite

show abstract

“…We used a microfluidic "T-channel" device to create the liquid interface. Two fluid streams were supplied to the microfluidic device using a low-cost constant pressure source flow system [31]. perform an experiment, the fluid interface was subjected to an electric field using the parallel-point electrode array and forced to displace by fDEP at different field frequencies (Fig 1b-d).…”

Section: Design and Fabrication Of Microfluidic Device With Embedded mentioning

confidence: 99%

“…Reynolds number these two fluids formed an interface with a large electrical mismatch between them. Each stream was injected at a constant flow rate (10 μL/min) into the device using a low-cost flow controller equipped with an externally pressurized fluidfilled cryogenic vial [31]. (Invitrogen).…”

Section: Chemicals and Reagentsmentioning

confidence: 99%

Monitoring microfluidic interfacial flows using impedance spectroscopy

Mavrogiannis

Desmond

et al. 2017

Sensors and Actuators B: Chemical

Self Cite

View full text Add to dashboard Cite

Microfluidic platforms capable of complex on-chip processing and liquid handling enable a wide variety of sensing, cellular, and material-related applications across a spectrum of disciplines in engineering and biology. However, there is a general lack of available microscale sensors capable of non-optically monitoring and quantifying on-chip fluid motion. Hence, many microfluidic systems are confined to the laboratory because their use requires optical microscopy. Here, we present a method for dynamically tracking laminar interfacial flows in microfluidic channels non-optically using impedance spectroscopy. Using a microfluidic T-channel, we generate a liquid interface by coflowing two different electrolyte streams side-by-side. The interface is driven through an array of "displacement" electrodes where it is electrokinetically deflected across the microchannel. The interfacial flow is monitored downstream using an array of interdigitated "impedance" electrodes which dynamically measure the electrochemical impedance near the surface of the flow channel. We demonstrate that the impedance spectrum is sensitively influenced by the position of the deflected interface. While laminar fluid interfaces are ubiquitous to microfluidic flows and used extensively in rheology and biomolecular detection, it is currently difficult to measure their position non-optically. The sensing method presented here enables the interfacial position to be dynamically determined without a microscope and provides a new tool for lowering the barriers to operating microfluidic devices outside the confines of a traditional laboratory.

show abstract

“…In attempts to control microfluids in a low-cost and portable manner, various techniques for driving liquid flows in microchannels have been proposed, such as compressed gas driven, 6,7 electro-osmotic flow, 8,9 capillary flow, 10,11 hydrostatic force, 12,13 and centrifugal force. 14,15 Although these previously reported techniques show acceptable performances in flow control in microchannels, they are either too complex due to the requirement of external equipments or limited in terms of sample types and volumes.…”

Section: Introductionmentioning

confidence: 99%

A microfluidic gas damper for stabilizing gas pressure in portable microfluidic systems

et al. 2016

View full text Add to dashboard Cite

Pressure fluctuations, which invariably occur in microfluidic systems, usually result in the unstable fluid delivery in microfluidic channels. In this work, a novel microfluidic gas damper is proposed and applied for providing stable fluid-driving pressures. Then, a pressure-driven flow setup is constructed to investigate the gas damping characteristics of our damper. Since the pressure-driven flow setup functions as a resistor-capacitor low-pass filter, the damper significantly decreases the amplitude of the input pressures via self-regulating its pneumatic resistance. In addition, the gas volume and pressure frequency are found to have direct effects on the pressure fluctuations. The practical application of the gas damper is examined through a portable pressure-driven system, which consists of an air blower, a gas damper, and a centrifuge tube. By periodically pressing the air blower, precise flow rates with low throughput ($9.64 ll min À1) and high throughput ($1367.15 ll min À1) are successfully delivered. Future integration of our microfluidic gas damper with miniaturized pressure generators (e.g., peristaltic or pressure-driven micropumps) can fully exploit the potential of the gas damper for low-cost, portable microfluidics where stable pressures or flow rates are required. Published by AIP Publishing. [http://dx

show abstract

Microfluidics made easy: A robust low-cost constant pressure flow controller for engineers and cell biologists

Cited by 52 publications

References 20 publications

Modular 3D Printed Compressed Air Driven Continuous‐Flow Systems for Chemical Synthesis

Modular 3D Printed Compressed Air Driven Continuous‐Flow Systems for Chemical Synthesis

Monitoring microfluidic interfacial flows using impedance spectroscopy

A microfluidic gas damper for stabilizing gas pressure in portable microfluidic systems

Contact Info

Product

Resources

About