Transverse electrodes for improved DNA hybridization in microchannels

The present study examines the modality, in which localized transverse electric fields can be successfully employed, to augment the rate of DNA hybridization at the capturing probes that are located further downstream relative to the inlet section of a rectangular microchannel. This is in accordance with an enhanced strength of convective transport that can be achieved, on account of increments in the wall zeta potential at the transverse electrode locations. In the present model, the overall convective transport, which is an implicit function of the magnitude and the location of the transverse electrical field being employed, is essentially coupled with the surface kinetics of the bare silica wall and also the kinetics that are involved in the dual mechanisms of DNA hybridization. Parameters that govern the overall transport phenomena, such as the pH of the inlet buffer, the length of the transverse electrodes, and the voltages at which these electrodes are maintained are critically examined, in an effort to obtain an optimized wall pH distribution, which in turn can ensure favorable DNA hybridization rates at the capturing probe locations. Practical constraints associated with the upper limits of the strength of the transverse electrical fields that can be employed are also critically analyzed, so as to ensure that an optimized rate of DNA hybridization can be achieved from the bio-microfluidic arrangement, without incurring any adverse effects associated with the overheating of the DNA molecules leading to their thermal denaturation.

[1]  James C Baygents,et al.  Electrically-driven fluid motion in channels with streamwise gradients of the electrical conductivity , 2001 .

[2]  C. Shu,et al.  Chaotic micromixers using two-layer crossing channels to exhibit fast mixing at low Reynolds numbers. , 2005, Lab on a chip.

[3]  V. Bloomfield,et al.  Brownian dynamics simulation of probe diffusion in DNA: effects of probe size, charge and DNA concentration. , 1995, Biophysical chemistry.

[4]  E. Hasselbrink,et al.  Zeta potential of microfluidic substrates: 1. Theory, experimental techniques, and effects on separations , 2004, Electrophoresis.

[5]  Feng Liu,et al.  Electro-osmotic flow and mixing in heterogeneous microchannels. , 2006, Physical review. E, Statistical, nonlinear, and soft matter physics.

[6]  A. Ewing,et al.  Electroosmotic flow control and monitoring with an applied radial voltage for capillary zone electrophoresis. , 1992, Analytical chemistry.

[7]  T. Johnson,et al.  Rapid microfluidic mixing. , 2002, Analytical chemistry.

[8]  J. Chai,et al.  Joule heating effect on electroosmotic flow and mass species transport in a microcapillary , 2004 .

[9]  N. Aubry,et al.  Electroosmotic mixing in microchannels. , 2004, Lab on a chip.

[10]  Gwo-Bin Lee,et al.  Dispersion control in microfluidic chips by localized zeta potential variation using the field effect , 2004, Electrophoresis.

[11]  A. Carré,et al.  Study of acid/base properties of oxide, oxide glass, and glass-ceramic surfaces , 1992 .

[12]  Cheng-Hsien Liu,et al.  A novel electrokinetic micromixer , 2003, TRANSDUCERS '03. 12th International Conference on Solid-State Sensors, Actuators and Microsystems. Digest of Technical Papers (Cat. No.03TH8664).

[13]  Ulrich J. Krull,et al.  Interfacial hybridization kinetics of oligonucleotides immobilized onto fused silica surfaces , 2003 .

[14]  D. Leighton,et al.  Binary oscillatory cross-flow electrophoresis: theory and experiments. , 1998, Journal of pharmaceutical sciences.

[15]  S. J. Wang,et al.  Effect of ionic strength, pH and polymer concentration on the separation of DNA fragments in the presence of electroosmotic flow. , 2000, Journal of chromatography. A.

[16]  Paul C. H. Li,et al.  A three-dimensional flow control concept for single-cell experiments on a microchip. 2. Fluorescein diacetate metabolism and calcium mobilization in a single yeast cell as stimulated by glucose and pH changes. , 2004, Analytical chemistry.

[17]  J. Yeomans,et al.  Using patterned substrates to promote mixing in microchannels. , 2002, Physical review. E, Statistical, nonlinear, and soft matter physics.

[18]  Matthew D. J. McGarry,et al.  Numerical simulations of laminar mixing surfaces in pulsatile microchannel flows , 2004, Math. Comput. Simul..

[19]  David Erickson,et al.  Modeling of DNA hybridization kinetics for spatially resolved biochips. , 2003, Analytical biochemistry.

[20]  George A. Parks,et al.  The Isoelectric Points of Solid Oxides, Solid Hydroxides, and Aqueous Hydroxo Complex Systems , 1965 .

[21]  A. Chauhan,et al.  DNA separation by EFFF in a microchannel. , 2005, Journal of colloid and interface science.

[22]  Robin H. Liu,et al.  Passive mixing in a three-dimensional serpentine microchannel , 2000, Journal of Microelectromechanical Systems.

[23]  George D. J. Phillies,et al.  Universal scaling equation for self-diffusion by macromolecules in solution , 1986 .

[24]  Cheng S. Lee,et al.  Factors affecting direct control of electroosmosis using an external electric field in capillary electrophoresis , 1991 .

[25]  Synthesis, characterization, and dynamics of a rod/sphere composite liquid , 1992 .

[26]  A. Chauhan,et al.  Taylor dispersion in cyclic electric field-flow fractionation , 2006 .

[27]  S. Chakraborty,et al.  Modeling of coupled momentum, heat and solute transport during DNA hybridization in a microchannel in the presence of electro-osmotic effects and axial pressure gradients , 2006 .

[28]  D. Graves,et al.  The biophysics of DNA hybridization with immobilized oligonucleotide probes. , 1995, Biophysical journal.

[29]  P. Russo,et al.  Tracer diffusion of proteins in DNA solutions , 1992 .

[30]  Ajdari Generation of transverse fluid currents and forces by an electric field: Electro-osmosis on charge-modulated and undulated surfaces. , 1996, Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics.

[31]  W. Birch,et al.  Molecular interactions between DNA and an aminated glass substrate. , 2003, Journal of colloid and interface science.

[32]  Nadine Aubry,et al.  Enhancement of microfluidic mixing using time pulsing. , 2003, Lab on a chip.

[33]  M. Madou,et al.  Characterization of DNA hybridization kinetics in a microfluidic flow channel , 2005, Sensors and Actuators B: Chemical.

[34]  P. Righetti,et al.  Isoelectric focusing of proteins and peptides in gel slabs and in capillaries1This humble review is dedicated to the memory of our Maestro, Prof. Harry Svensson-Rilbe, who died on July 10, 1997 at the age of 84 years.1 , 1998 .

[35]  Michelle D. Wang,et al.  Reduction-of-dimensionality kinetics at reaction-limited cell surface receptors. , 1994, Biophysical journal.