Dielectric characterization of complete mononuclear and polymorphonuclear blood cell subpopulations for label-free discrimination.

Dielectric spectroscopy is a powerful technique for the elucidation of a number of important cell biophysical properties, and it can provide information about cell morphology, physiological state, viability and identity. A high-impact application for dielectric cell analysis would be microfluidic flow-through impedance sensing to perform what is perhaps the most routinely ordered medical diagnostic assay, a complete blood count with white blood cell differential enumeration. To assess the biophysical feasibility of such an analysis, we obtained reference dielectric measurements of the complete complement of purified leukocyte subpopulations using the dielectrophoretic crossover frequency method.

Enrichment of putative stem cells from adipose tissue using dielectrophoretic field-flow fractionation.

We have applied the microfluidic cell separation method of dielectrophoretic field-flow fractionation (DEP-FFF) to the enrichment of a putative stem cell population from an enzyme-digested adipose tissue derived cell suspension. A DEP-FFF separator device was constructed using a novel microfluidic-microelectronic hybrid flex-circuit fabrication approach that is scaleable and anticipates future low-cost volume manufacturing. We report the separation of a nucleated cell fraction from cell debris and the bulk of the erythrocyte population, with the relatively rare (<2% starting concentration) NG2-positive cell population (pericytes and/or putative progenitor cells) being enriched up to 14-fold.

A Continuous-Flow Polymerase Chain Reaction Microchip With Regional Velocity Control.

This paper presents a continuous-flow polymerase chain reaction (PCR) microchip with a serpentine microchannel of varying width for "regional velocity control." Varying the channel width by incorporating expanding and contracting conduits made it possible to control DNA sample velocities for the optimization of the exposure times of the sample to each temperature phase while minimizing the transitional periods during temperature transitions. A finite element analysis (FEA) and semi-analytical heat transfer model was used to determine the distances between the three heating assemblies that are responsible for creating the denaturation (96 degrees C), hybridization (60 degrees C), and extension (72 degrees C) temperature zones within the microchip.

Dielectrophoresis-based programmable fluidic processors.

Droplet-based programmable processors promise to offer solutions to a wide range of applications in which chemical and biological analysis and/or small-scale synthesis are required, suggesting they will become the microfluidic equivalents of microprocessors by offering off-the-shelf solutions for almost any fluid based analysis or small scale synthesis problem. A general purpose droplet processor should be able to manipulate droplets of different compositions (including those that are electrically conductive or insulating and those of polar or non-polar nature), to control reagent titrations accurately, and to remain free of contamination and carry over on its reaction surfaces. In this article we discuss the application of dielectrophoresis to droplet based processors and demonstrate that it can provide the means for accurately titrating, moving and mixing polar or non-polar droplets whether they are electrically conductive or not.

Dielectrically Addressable Microspheres Engineered Using Self-Assembled Monolayers.

We have used self-assembled monolayer techniques to produce a new class of microspheres with specifically engineered dielectric properties to enable their dielectrophoretic manipulation and identification in microsystems. Dielectrophoresis is an electrokinetic phenomenon that exploits frequency-dependent polarizability differences between a particle and its suspending medium to drive the movement of the particle toward or away from the high-field regions of an inhomogeneous electric field. While dielectrophoretic methods have been used extensively for cell manipulation, separation, and identification, we wished to extend the applicability of dielectrophoresis to molecular analysis by developing a panel of dielectric microspheres or "handles".