Background

It has been realized in recent years that the classical concept of microfluidics, i.e., the confinement of the flow of single phase liquids to networks of narrow channels, has some fundamental drawbacks. The most obvious one is the fact that in small dimensions, the Reynolds number Re of the flow rarely exceeds unity, such that the flow is purely laminar (the threshold for turbulence is Re > 200). As a consequence, mixing two substances is difficult, and may proceed only by diffusion or, in some cases, be achieved via viscous dephasing. Hence, there has been considerable development towards the use of isolated water droplets suspended in an oily phase. The main advantage considered in this context is the twisty flow pattern emerging within the droplets when they are moved through the channel system. Mixing of two aqueous components is achieved in this way within each droplet separately, and is found to proceed quite efficiently.

Another advantage of this approach, which has been rarely referred to (if at all), is that each droplet may carry chemically different contents. If the volume fraction of the oily phase is kept small, the droplets will touch each other, separated only by a thin oil lamella. A chemical reaction may then be induced, at a precisely defined time, by destroying the lamella, e.g., by local heating.

Discrete flow (droplet-based)

Electrowetting actuation

Electrowetting has recently been used successfully as one of several techniques used to actuate microdroplets in a digital microfluidic device. In many of these applications electowetting allows large numbers of droplets to be independently manipulated under direct electrical control without the use of pumps, valves or even fixed channels. The phenomenon of electowetting can be understood in terms of the forces that result from the applied electric field. The fringing field at the corners of the electrolyte droplet tend to pull the droplet down onto the electrode, lowering the macroscopic contact angle, and increasing the droplet contact area. (Wikipedia article)

ElectroWetting-On-Dielectric (EWOD), which is based on changing the wettability of liquids on a dielectric solid surface by varying the electric potential. This method offers advantages over conventional continuious-flow microfluidic chips, by way of significantly reduced sample size, as well as reconfigurability and scalability of architecture. The similarity of the EWOD system with digital microelectronic systems, has led to the term “digital microfluidics” [1]. The phenomenon of EWOD has been demonstrated for dispensing, cutting, and transport of tiny droplets [2, 3], and more recently, a proof-of-concept has been demonstrated for an integrated lab-on-a-chip system for clinical diagnostic applications

Research groups

• Duke University
• MEMS Lab, Washington University, Karl F. Böhringer
• Harvard, Weitz Group
• Wheeler Microfluidics Laboratory
• Garrell research group, UCLA
• Kim's Group, UCLA
• Max Plank Institute

Private Companies

• Advanced Liquid Logic
• Raindance Technologies

Web links

• Digital Microfluidics on Wikipedia
• Slashdot article about Duke

References

1. Chang YH, Lee GB, Huang FC, Chen YY, and Lin JL. Integrated polymerase chain reaction chips utilizing digital microfluidics. Biomed Microdevices. 2006 Sep;8(3):215-25. DOI:10.1007/s10544-006-8171-y | PubMed ID:16718406 | HubMed [1]
2. Srinivasan V, Pamula VK, and Fair RB. An integrated digital microfluidic lab-on-a-chip for clinical diagnostics on human physiological fluids. Lab Chip. 2004 Aug;4(4):310-5. DOI:10.1039/b403341h | PubMed ID:15269796 | HubMed [2]
3. Satoh W, Hosono H, and Suzuki H. On-chip microfluidic transport and mixing using electrowetting and incorporation of sensing functions. Anal Chem. 2005 Nov 1;77(21):6857-63. DOI:10.1021/ac050821s | PubMed ID:16255583 | HubMed [3]
4. Haeberle S and Zengerle R. Microfluidic platforms for lab-on-a-chip applications. Lab Chip. 2007 Sep;7(9):1094-110. DOI:10.1039/b706364b | PubMed ID:17713606 | HubMed [4]
5. Chatterjee D, Hetayothin B, Wheeler AR, King DJ, and Garrell RL. Droplet-based microfluidics with nonaqueous solvents and solutions. Lab Chip. 2006 Feb;6(2):199-206. DOI:10.1039/b515566e | PubMed ID:16450028 | HubMed [5]
6. Lee AP. Digital microfluidics for bioassays and drug delivery. Conf Proc IEEE Eng Med Biol Soc. 2004;2004:5392. DOI:10.1109/IEMBS.2004.1404505 | PubMed ID:17271562 | HubMed [6]
7. Pollack MG, Shenderov AD, and Fair RB. Electrowetting-based actuation of droplets for integrated microfluidics. Lab Chip. 2002 May;2(2):96-101. DOI:10.1039/b110474h | PubMed ID:15100841 | HubMed [7]
8. Paik P, Pamula VK, Pollack MG, and Fair RB. Electrowetting-based droplet mixers for microfluidic systems. Lab Chip. 2003 Feb;3(1):28-33. DOI:10.1039/b210825a | PubMed ID:15100802 | HubMed [8]
9. Jang LS, Lin GH, Lin YL, Hsu CY, Kan WH, and Chen CH. Simulation and experimentation of a microfluidic device based on electrowetting on dielectric. Biomed Microdevices. 2007 Dec;9(6):777-86. DOI:10.1007/s10544-007-9089-8 | PubMed ID:17520369 | HubMed [9]
10. Dubois P, Marchand G, Fouillet Y, Berthier J, Douki T, Hassine F, Gmouh S, and Vaultier M. Ionic liquid droplet as e-microreactor. Anal Chem. 2006 Jul 15;78(14):4909-17. DOI:10.1021/ac060481q | PubMed ID:16841910 | HubMed [10]

All Medline abstracts: PubMed | HubMed

Books

• Microdrops and Digital Microfluidics, by Jean Berthier
• Digital Microfluidic Biochips: Synthesis, Testing, and Reconfiguration Techniques, by Krishnendu Chakrabarty, Fei Su