Dielectrophoresis for the manipulation of nanobioparticles
Identifieur interne : 002C59 ( Main/Exploration ); précédent : 002C58; suivant : 002C60Dielectrophoresis for the manipulation of nanobioparticles
Auteurs : Blanca H. Lapizco-Encinas [Mexique] ; Marco Rito-Palomares [Mexique]Source :
- ELECTROPHORESIS [ 0173-0835 ] ; 2007-12.
English descriptors
- Teeft :
- Anal, Appl, Asbury, Avidin, Bacterial chromosomes, Bacterial spores, Bead, Biophys, Brownian, Brownian motion, Capsid, Cell lysis, Chem, Chromosome, Coli, Coli chromosomes, Collection ratio, Conductance, Conductivity, Conf, Cpmv, Crossover, Crossover frequencies, Crossover frequency, Dielectric, Dielectric properties, Dielectrophoretic, Dielectrophoretic behavior, Dielectrophoretic force, Dielectrophoretic forces, Dielectrophoretic manipulation, Dielectrophoretic response, Dielectrophoretic separation, Electric field, Electric field gradient, Electric fields, Electrode, Electrode array, Electrode cages, Electrode edges, Electrodes edges, Electrohydrodynamic flow, Electrophoretic, Electrophoretic force, Field cages, Field gradient, Field intensity, First report, Fluorescently, Gmbh, Gold electrodes, High frequency, Ieee, Ieee trans, Important research group, Important role, Influenza virus, Joule heating, Kgaa, Kurosawa, Latex beads, Latex particles, Main channel, Main contribution, Manipulation, Mathematical modeling, Medium conductivities, Medium conductivity, Microchannel, Microdevice, Miniaturization, Modeling, Modeling results, Molecular patterning, Molecule, Monterrey, Morgan research group, Nanobioparticles, Nanopipette, Negative dielectrophoretic, Negative dielectrophoretic behavior, Nonenveloped virus, Nonuniform, Original publication, Particle size, Phys, Physical separation, Pipette, Plant virus, Polarizability, Polarization effects, Polymer, Polynomial electrodes, Positive dielectrophoretic, Positive dielectrophoretic behavior, Previous work, Protein concentration, Protein molecules, Protein solution, Research group, Research groups, Research studies, Research work, Schematic representation, Selective dielectrophoretic, Sendai virus, Similar results, Similar size, Size fractionation, Spore, Subtilis spores, Surface conductance, Trans, Vaccinia virus, Verlag, Verlag gmbh, Viral, Viral capsids, Viral particles, Virus, Wafer, Washizu, Washizu group, Weinheim, Weinheim electrophoresis.
Abstract
Dielectrophoresis (DEP) is a nondestructive electrokinetic mechanism with great potential for the manipulation of bioparticles. DEP is the movement of particles induced by polarization effects in nonuniform electric fields. Since the 1960s, this technique has been successfully used for the manipulation of microbioparticles, such as microorganisms. Moreover, due to the advances in microfabrication techniques, that allowed progressively smaller microstructures to be constructed, DEP can now be used for the manipulation of nanobioparticles. The first research studies on the DEP of nanobioparticles started in the 1990s. Since then, many research groups have carried out outstanding work with DEP of nanobioparticles such as macromolecules, virus, and spores. However, the need of a critical report that integrates these findings is evident. The aim of the present review is to depict the state‐of–the‐art on the use of DEP for the separation of nanobioparticles and the potential trends of novel applications of this technique. This review compiles and analyzes the significant findings obtained by many researchers. This publication is intended to provide the reader with state‐of‐the‐art information on many research studies focused on DEP to handle nanobioparticles.
Url:
DOI: 10.1002/elps.200700303
Affiliations:
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DEP is the movement of particles induced by polarization effects in nonuniform electric fields. Since the 1960s, this technique has been successfully used for the manipulation of microbioparticles, such as microorganisms. Moreover, due to the advances in microfabrication techniques, that allowed progressively smaller microstructures to be constructed, DEP can now be used for the manipulation of nanobioparticles. The first research studies on the DEP of nanobioparticles started in the 1990s. Since then, many research groups have carried out outstanding work with DEP of nanobioparticles such as macromolecules, virus, and spores. However, the need of a critical report that integrates these findings is evident. The aim of the present review is to depict the state‐of–the‐art on the use of DEP for the separation of nanobioparticles and the potential trends of novel applications of this technique. This review compiles and analyzes the significant findings obtained by many researchers. 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