Daniel Heineck scite author profile

The 20th century has seen tremendous innovation of dielectrophoresis (DEP) technologies, with applications being developed in areas ranging from industrial processing to micro‐ and nanoscale biotechnology. From 2010 to present day, there have been 981 publications about DEP. Of over 2600 DEP patents held by the United States Patent and Trademark Office, 106 were filed in 2019 alone. This review focuses on DEP‐based technologies and application developments between 2010 and 2020, with an aim to highlight the progress and to identify potential areas for future research. A major trend over the last 10 years has been the use of DEP techniques for biological and clinical applications. It has been used in various forms on a diverse array of biologically derived molecules and particles to manipulate and study them including proteins, exosomes, bacteria, yeast, stem cells, cancer cells, and blood cells. DEP has also been used to manipulate nano‐ and micron‐sized particles in order to fabricate different structures. The next 10 years are likely to see the increase in DEP‐related patent applications begin to result in a greater level of technology commercialization. Also during this time, innovations in DEP technology will likely be leveraged to continue the existing trend to further biological and medical‐focused applications as well as applications in microfabrication. As a tool leveraged by engineering and imaginative scientific design, DEP offers unique capabilities to manipulate small particles in precise ways that can help solve problems and enable scientific inquiry that cannot be addressed using conventional methods.

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Automated fluorescence quantification of extracellular vesicles collected from blood plasma using dielectrophoresis

Gustafson

Huynh

Heineck

et al. 2021

Lab Chip

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Detecting cancer biomarkers in blood: challenges for new molecular diagnostic and point-of-care tests using cell-free nucleic acids

Lewis

Heineck

Heller

2015

Expert Review of Molecular Diagnostics

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As we move into the era of individualized cancer treatment, the need for more sophisticated cancer diagnostics has emerged. Cell-free (cf) nucleic acids (cf-DNA, cf-RNA) and other cellular nanoparticulates are now considered important and selective biomarkers. There is great hope that blood-borne cf-nucleic acids can be used for 'liquid biopsies', replacing more invasive tissue biopsies to analyze cancer mutations and monitor therapy. Conventional techniques for cf-nucleic acid biomarker isolation from blood are generally time-consuming, complicated and expensive. They require relatively large blood samples, which must be processed to serum or plasma before isolation of biomarkers can proceed. Such cumbersome sample preparation also limits the widespread use of powerful, downstream genomic analyses, including PCR and DNA sequencing. These limitations also preclude rapid, point-of-care diagnostic applications. Thus, new technologies that allow rapid isolation of biomarkers directly from blood will permit seamless sample-to-answer solutions that enable next-generation point-of-care molecular diagnostics.

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Zinc Tin Oxide Thin-Film-Transistor Enhancement/Depletion Inverter

Heineck

McFarlane

Wager

2009

IEEE Electron Device Lett.

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A fabrication process to create a zinc tin oxide (ZTO) thin-film-transistor (TFT) enhancement/depletion inverter using 15-μm channel lengths is developed. Both enhancement-and depletion-mode staggered bottom-gate ZTO TFTs are simultaneously fabricated on a single substrate using a single sputter target and postdeposition anneal step. At a rail voltage of 10 V, this inverter has a gain of 10.6 V/V. Index Terms-Amorphous oxide semiconductor (AOS), enhancement/depletion (E/D) inverter, oxide electronics, thin-film transistor (TFT), zinc tin oxide (ZTO).

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Nanofiber Near-Field Light–Matter Interactions for Enhanced Detection of Molecular Level Displacements and Dynamics

et al. 2013

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We experimentally demonstrate that plasmonic nanoparticles embedded in the evanescent field of subwavelength optical waveguides (WGs) are highly sensitive to distances normal to the propagation of light, showing an ~10× increase in spatial resolution compared to the optical field decay of the WG. The scattering cross-section of the Au nanoparticle is increased by the plasmon-dielectric coupling interaction when the nanoparticle is placed near the dielectric surface of the WG, and the decay of the scattering signal is enhanced, showing angstrom level distance sensitivity within 10 nm from the WG. Numerical studies with the finite-difference time-domain (FDTD) method correlate well with the experimental results. To demonstrate real-time monitoring of a single molecule stretching in the evanescent field, we linked individual single-stranded DNA molecules between the WG and plasmonic nanoparticles and pushed on the nanoparticles with fluidic forces. The simple design and ease of obtaining optical feedback on molecular displacements makes our approach ideal for new in situ force sensing devices, imaging technologies, and high-throughput molecular analysis.

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Electrokinetic device design and constraints for use in high conductance solutions

2017

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The quest for new cell-free DNA and exosome biomarker-based molecular diagnostics require fast and efficient sample preparation techniques. Conventional methods for isolating these biomarkers from blood are both time-consuming and laborious. New electrokinetic microarray devices using dielectrophoresis (DEP) to isolate cell-free DNA and exosome biomarkers have now greatly improved the sample preparation process. Nevertheless, these devices still have some limitations when used with high conductance biological fluids, e.g. blood, plasma, and serum. This study demonstrates that electrochemical damage may occur on the platinum electrodes of DEP microarray devices. It further examines two model device designs that include a parallel wire arrangement and a planar array. Effective isolation of fluorescent beads with parallel wires is shown under low-conductance conditions (10 S/m), but electrothermal flow overcomes DEP forces under high conductance conditions (>0.1 S/m). Planar devices are shown to be effective under high conductance conditions (∼1 S/m) without the deleterious effects of electrothermal flow. This study provides new insights into design compromises and limitations for producing future electrokinetic devices for better performance with high conductance solutions.

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Stimulus-Responsive Light Coupling and Modulation with Nanofiber Waveguide Junctions

et al. 2012

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We report a systematic study of light coupling at junctions of overlapping SnO(2) nanofiber waveguides (WGs) as a function of gap separation and guided wavelength. The junctions were assembled on silica substrates using micromanipulation techniques and the gap separation was controlled by depositing thin self-assembled polyelectrolyte coatings at the fiber junctions. We demonstrate that the coupling efficiency is strongly dependent on the gap separation, showing strong fluctuations (0.1 dB/nm) in the power transfer when the separation between nanofibers changes by as little as 2 nm. Experimental results correlate well with numerical simulations using three-dimensional finite-difference time-domain techniques. To demonstrate the feasibility of using coupled nanofiber WGs to modulate light, we encased the junctions in an environment-responsive matrix and exposed the junctions to gaseous vapor. The nanofiber junctions show an ~95% (or ~80%) modulation of the guided 450 nm (or 510 nm) light upon interaction with the gaseous molecules. The results reveal a unique nanofiber-based sensing scheme that does not require a change in the refractive index to detect stimuli, suggesting these structures could play important roles in localized sensing devices including force-based measurements or novel chemically induced light modulators.

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Electrochemical attack and corrosion of platinum electrodes in dielectrophoretic diagnostic devices

Heineck¹,

Sarno

Kim

et al. 2020

Anal Bioanal Chem

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Daniel Heineck

Dielectrophoresis: Developments and applications from 2010 to 2020

Automated fluorescence quantification of extracellular vesicles collected from blood plasma using dielectrophoresis

Detecting cancer biomarkers in blood: challenges for new molecular diagnostic and point-of-care tests using cell-free nucleic acids

Zinc Tin Oxide Thin-Film-Transistor Enhancement/Depletion Inverter

Nanofiber Near-Field Light–Matter Interactions for Enhanced Detection of Molecular Level Displacements and Dynamics

Electrokinetic device design and constraints for use in high conductance solutions

Stimulus-Responsive Light Coupling and Modulation with Nanofiber Waveguide Junctions

Electrochemical attack and corrosion of platinum electrodes in dielectrophoretic diagnostic devices

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