Accumulation and filtering of nanoparticles in microchannels using electrohydrodynamically induced vortical flows

We present an approach for the accumulation and filtering of nano‐ and microparticles in microfluidic devices that is based on the generation of electric traveling waves in the radio‐frequency range. Upon application of the electric field via a microelectrode array, complex particle trajectories and particle accumulation are observed in well‐defined regions in a microchannel. Through the quantitative mapping of the 3‐D flow pattern using two‐focus fluorescence cross‐correlation spectroscopy, two vortices could be identified as one of the sources of the force field that induces the formation of particle clouds. Dielectrophoretic forces that directly act on the particles are the second source of the force field. A thorough 2‐D finite element analysis identifies the electric traveling wave mechanism as the cause for the unexpected flow behavior observed. Based on these findings, strategies are discussed, first, for avoiding the vortices to optimize electrohydrodynamic micropumps and, secondly, for utilizing the vortices in the development of microdevices for efficient particle accumulation, separation, and filtering. Such devices may find numerous biomedical applications when highly diluted nano‐ and microsuspensions have to be processed.

[1]  W. Webb,et al.  Active protein transport through plastid tubules: velocity quantified by fluorescence correlation spectroscopy. , 2000, Journal of cell science.

[2]  J. Lasheras,et al.  Particle dispersion in the developing free shear layer. Part 1. Unforced flow , 1992, Journal of Fluid Mechanics.

[3]  G. Fuhr,et al.  Traveling‐wave dielectrophoresis of microparticles , 1992, Electrophoresis.

[4]  E. Meiburg,et al.  Dynamics of small, spherical particles in vortical and stagnation point flow fields , 1997 .

[5]  W. M. Haynes CRC Handbook of Chemistry and Physics , 1990 .

[6]  H. Watarai,et al.  Magnetophoretic Behavior of Single Polystyrene Particles in Aqueous Manganese(II) Chloride , 2001, Analytical sciences : the international journal of the Japan Society for Analytical Chemistry.

[7]  Nicolas G Green,et al.  Numerical simulation of travelling wave induced electrothermal fluid flow , 2004 .

[8]  M. Eigen,et al.  Two-beam cross-correlation:  a method to characterize transport phenomena in micrometer-sized structures. , 1999, Analytical chemistry.

[9]  J. Chung,et al.  Effects of vortex pairing on particle dispersion in turbulent shear flows , 1987 .

[10]  Volker Buschmann,et al.  Application of Fluorescence Correlation Spectroscopy for Velocity Imaging in Microfluidic Devices , 2004, Applied spectroscopy.

[11]  O. Salata,et al.  Applications of nanoparticles in biology and medicine , 2004, Journal of nanobiotechnology.

[12]  Martin Stelzle,et al.  Versatile chip-based tool for the controlled manipulation of microparticles in biology using high Frequency Electromagnetic Fields , 2004 .

[13]  H. Morgan,et al.  Ac electrokinetics: a review of forces in microelectrode structures , 1998 .

[14]  Petra Schwille,et al.  Spatial two-photon fluorescence cross-correlation spectroscopy for controlling molecular transport in microfluidic structures. , 2002, Analytical chemistry.

[15]  M. Stelzle,et al.  Microdevices for manipulation and accumulation of micro‐ and nanoparticles by dielectrophoresis , 2003, Electrophoresis.

[16]  Eckart Meiburg,et al.  THE ACCUMULATION AND DISPERSION OF HEAVY PARTICLES IN FORCED TWO-DIMENSIONAL MIXING LAYERS. I: THE FUNDAMENTAL AND SUBHARMONIC CASES , 1994 .

[17]  Hywel Morgan,et al.  RAPID COMMUNICATION: Separation of submicrometre particles using a combination of dielectrophoretic and electrohydrodynamic forces , 1998 .

[18]  J. Lasheras,et al.  Particle dispersion in the developing free shear layer. Part 2. Forced flow , 1992, Journal of Fluid Mechanics.

[19]  Watt W. Webb,et al.  Fluorescence correlation spectroscopy. III. Uniform translation and laminar flow , 1978 .

[20]  E. Elson,et al.  Fluorescence correlation spectroscopy. I. Conceptual basis and theory , 1974 .

[21]  G. Gradl,et al.  A 3-D microelectrode system for handling and caging single cells and particles , 1999 .

[22]  Heino,et al.  Hydrodynamic flow profiling in microchannel structures by single molecule fluorescence correlation spectroscopy , 2000, Analytical chemistry.

[23]  Claus Duschl,et al.  Controlling electrohydrodynamic pumping in microchannels through defined temperature fields , 2006 .

[24]  M. Mcdonnell,et al.  Optimizing particle collection for enhanced surface-based biosensors , 2003, IEEE Engineering in Medicine and Biology Magazine.

[25]  L. White,et al.  Lateral separation of colloids or cells by dielectrophoresis augmented by AC electroosmosis. , 2005, Journal of colloid and interface science.

[26]  Volker Buschmann,et al.  Fluorescence correlation spectroscopy for flow rate imaging and monitoring--optimization, limitations and artifacts. , 2005, Lab on a chip.

[27]  J. R. Melcher,et al.  CONTINUUM ELECTROMECHANICS GROUP: TRAVELING WAVE BULK ELECTROCONVECTION INDUCED ACROSS A TEMPERATURE GRADIENT. , 1967 .

[28]  Pekka Hänninen,et al.  Ultrasonic enrichment of microspheres for ultrasensitive biomedical analysis in confocal laser-scanning fluorescence detection , 2004 .

[29]  R. Rigler,et al.  Submillisecond detection of single rhodamine molecules in water , 1994, Journal of Fluorescence.