A. Ezekiel Smith scite author profile

We present the development of a continuous-flow, "dielectrophoretic spectrometer" based on insulative DEP techniques and three-dimensional geometric design. Hot-embossed thermoplastic devices allow for high-throughput analysis and geometric control of electric fields via ridged microstructures patterned in a high width-to-depth aspect ratio (250:1) channel. We manipulate particles with dc-biased, ac electric fields and generate continuous-output streams of particles with a transverse outlet position specified by linear and nonlinear particle mobilities. We show, with simulation and experiment, that characteristic shape factors can be defined that capture the effects of constrictions in channel depth and that modulating the angle of these constrictions changes the resulting local DEP force. Microdevices are fabricated with an insulative constriction in channel depth, whose angle of incidence with the direction of flow varies continuously across the channel width. The resulting electric field gradients enable demonstration of a dielectrophoretic spectrometer that separates particles and controls their transverse channel position.

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Microfluidic devices for terahertz spectroscopy of biomolecules

George¹,

Hui²,

Rana³

et al. 2008

Opt. Express

116

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We demonstrate microfluidic devices for terahertz spectroscopy of biomolecules in aqueous solutions. The devices are fabricated out of a plastic material that is both mechanically rigid and optically transparent with near-zero dispersion in the terahertz frequency range. Using a lowpower terahertz time-domain spectrometer, we experimentally measure the absorption spectra of the vibrational modes of bovine serum albumin from 0.5 - 2.5 THz and find good agreement with previously reported data obtained using large-volume solutions and a high-power free-electron laser. Our results demonstrate the feasibility of performing high sensitivity terahertz spectroscopy of biomolecules in aqueous solutions with detectable molecular quantities as small as 10 picomoles using microfluidic devices.

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Hybrid cavity-coupled plasmonic biosensors for low concentration, label-free and selective biomolecular detection

Vázquez‐Guardado¹,

Smith²,

Wilson³

et al. 2016

Opt. Express

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Simple optical techniques that can accurately and selectively identify organic and inorganic material in a reproducible manner are of paramount importance in biological sensing applications. In this work, we demonstrate that a nanoimprinted plasmonic pattern with locked-in dimensions supports sharp deterministic hybrid resonances when coupled with an optical cavity suitable for high sensitive surface detection. The surface sensing property of this hybrid system is quantified by precise atomic layer growth of aluminum oxide using the atomic layer deposition technique. The analyte specific sensing ability is demonstrated in the detection of two dissimilar analytes, inorganic amine-coated iron oxide nanoparticles and organic streptavidin protein. Femto to nanomolar detection limits were achieved with the proposed coupled plasmonic system based on the versatile and robust soft nanoimprinting technique, which promises practical low cost biosensors.

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Dielectrophoretic Particle Manipulation in Ridged Microchannels

Smith

Hawkins

Baldasaro

et al. 2006

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This work presents continuous-flow particle sorting at low applied fields (30 V/cm) using electrodeless dielectrophoresis [2–7] in ridged polymeric microstructures. Particle manipulation and sorting is critical in analysis of cellular systems and subpopulations, water monitoring, soil analysis, and colloidal synthesis. This technique is developed with a view toward sorting of cellular systems, and offers advantages over other particle processing techniques in its ability to sort particles over small (~100 μm) spatial scales and rapid (<1s) time scales while operating under the low electric fields required when using solutions of physiological salinity.

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A. Ezekiel Smith

Continuous-Flow Particle Separation by 3D Insulative Dielectrophoresis Using Coherently Shaped, dc-Biased, ac Electric Fields

Microfluidic devices for terahertz spectroscopy of biomolecules

Hybrid cavity-coupled plasmonic biosensors for low concentration, label-free and selective biomolecular detection

Dielectrophoretic Particle Manipulation in Ridged Microchannels

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