Tag Archives: electro
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Submitted, 2016: Automated electrorotation shows the electrokinetic separation in pancreatic cancer cells is robust to acquired chemotherapy resistance, serum starvation, and epithelial-to-mesenchymal transition
![10 Oct 2016: MicroTAS 2016: Separation of cancer-cell-derived microvesicles and exosomes in microfluidic Fabry-Perot acoustic resonators](https://blogs.cornell.edu/kirbyresearch/wp-content/themes/gridster-lite/img/defaultthumb.png)
10 Oct 2016: MicroTAS 2016: Separation of cancer-cell-derived microvesicles and exosomes in microfluidic Fabry-Perot acoustic resonators
![](https://blogs.cornell.edu/kirbyresearch/files/2016/07/2016_barbati_electrophoresis_thumb-q0bjtv-225x158.png)
Accepted, Electrophoresis, 2016: Surface Conductivity in Electrokinetic Systems with Porous and Charged Interfaces: Analytical Approximations and Numerical Results
![](https://blogs.cornell.edu/kirbyresearch/files/2015/08/2015_bono_plosone_thumb-241jnum-225x158.jpg)
PLoS ONE, 2015: Measurement of Lipid Accumulation in Chlorella vulgaris via Flow Cytometry and Liquid-State 1H NMR Spectroscopy for Development of an NMR-Traceable Flow Cytometry Protocol
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16 Nov 2014: AES Electrophoresis Society Meeting: Electrokinetic Manipulation for Characterization and Capture of Circulating Tumor Cells
![](https://blogs.cornell.edu/kirbyresearch/files/2014/08/201408_hartman_GRC_poster-1aieugc-225x158.jpg)
3 Aug 2014: Gordon Research Conference on Rare Cells in Circulation: Informing high performance capture of circulating tumor cells using a hybrid dielectrophoresis and immunocapture microdevice
![](https://blogs.cornell.edu/kirbyresearch/files/2014/06/201406_lannin_GRC_poster-1uyo3ku-225x158.jpg)
23 June 2014: Gordon Research Conference on Bioanalytical Sensors: Electrorotation of Cancer Cells to Optimize Performance of Dielectrophoresis Capture Devices
![](https://blogs.cornell.edu/kirbyresearch/files/2014/06/201406_lannin_GRS_talk-1726d01-225x158.jpg)
21 June 2014: Gordon Research Seminar on Bioanalytical Sensors: Electrorotation of Cancer Cells to Optimize Performance of Dielectrophoresis Capture Devices
![7 Mar 2014: Sibley Graduate Research Symposium: Electrorotation of Cancer Cells to Optimize Performance of Dielectrophoresis Capture Devices](https://blogs.cornell.edu/kirbyresearch/wp-content/themes/gridster-lite/img/defaultthumb.png)
7 Mar 2014: Sibley Graduate Research Symposium: Electrorotation of Cancer Cells to Optimize Performance of Dielectrophoresis Capture Devices
![](https://blogs.cornell.edu/kirbyresearch/files/2014/01/201401_smith_lab_automation-2n7m698-225x158.jpg)
18 Jan 2014: Society for Lab Automation and Screening: Circulating tumor cell (CTC) cancer biomarkers using geometrically enhanced differential immunocapture (GEDI) microdevices
![17 Jan 2014: Edwards Lecture, Oregon State University: Geometrically Enhanced Differential Immunocapture: Using obstacle arrays in microfluidic devices to enhance efficient and pure rare cell capture from fluid suspensions](https://blogs.cornell.edu/kirbyresearch/wp-content/themes/gridster-lite/img/defaultthumb.png)
17 Jan 2014: Edwards Lecture, Oregon State University: Geometrically Enhanced Differential Immunocapture: Using obstacle arrays in microfluidic devices to enhance efficient and pure rare cell capture from fluid suspensions
![24 Nov 2013: APS Division of Fluid Dynamics: Streaming potential and conductivity measurements reveal electrokinetic properties of porous and charged layers](https://blogs.cornell.edu/kirbyresearch/wp-content/themes/gridster-lite/img/defaultthumb.png)
24 Nov 2013: APS Division of Fluid Dynamics: Streaming potential and conductivity measurements reveal electrokinetic properties of porous and charged layers
![27 Oct 2013: MicroTAS: Enrichment of prostate cancer cells from blood cells with a hybrid dielectrophoresis and immunocapture microfluidic system](https://blogs.cornell.edu/kirbyresearch/wp-content/themes/gridster-lite/img/defaultthumb.png)
27 Oct 2013: MicroTAS: Enrichment of prostate cancer cells from blood cells with a hybrid dielectrophoresis and immunocapture microfluidic system
![19 Sep 2013: Cornell NanoScale Science & Technology Facility Annual Meeting: A Hybrid Dielectrophoresis and Immunocapture Microfluidic System for Enhanced Rare Cell Capture](https://blogs.cornell.edu/kirbyresearch/wp-content/themes/gridster-lite/img/defaultthumb.png)
19 Sep 2013: Cornell NanoScale Science & Technology Facility Annual Meeting: A Hybrid Dielectrophoresis and Immunocapture Microfluidic System for Enhanced Rare Cell Capture
![](https://blogs.cornell.edu/kirbyresearch/files/2013/07/201307_asme_ses-1vr0be0-225x158.jpg)
28 Jul 2013: SES Summer Meeting: Electrokinetic response in systems with fluid-permeable and charged layers
![](https://blogs.cornell.edu/kirbyresearch/files/2016/07/2013_huang_biomedicalmicrodevices_thumb-25d9ggp-225x158.jpg)
Biomedical Microdevices, 2013: Enrichment of prostate cancer cells from blood cells with a hybrid dielectrophoresis and Immunocapture microfluidic system
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Electrophoresis, 2009: Transient zeta-potential measurements in hydrophobic, TOPAS microfluidic substrates
![](https://blogs.cornell.edu/kirbyresearch/files/2009/01/2009_hawkins_methodsinbioengineering_thumb-1qv5xo2-225x158.jpg)
Methods In Bioengineering: Biomicrofabrication and Biomicrofluidics, 2009: Dielectrophoresis for Cell and Particle Manipulations
![](https://blogs.cornell.edu/kirbyresearch/files/2016/07/2008b_tandon_electrophoresis_thumb-w8jehd-225x158.jpg)
Electrophoresis, 2008: Zeta potential and electroosmotic mobility in microfluidic devices fabricated from hydrophobic polymers: 2. Slip and interfacial water structure
![](https://blogs.cornell.edu/kirbyresearch/files/2016/07/2008_tandon_electrophoresis_thumb-1jivj59-225x158.jpg)
Electrophoresis, 2008: Zeta potential and electroosmotic mobility in microfluidic devices fabricated from hydrophobic polymers: 1. The origins of charge
![](https://blogs.cornell.edu/kirbyresearch/files/2016/10/2007_hawkins_analyticalchemistry_thumb-1jgmsht-225x158.jpg)
Analytical Chemistry, 2007: Continuous-Flow Particle Separation by 3D Insulative Dielectrophoresis Using Coherently Shaped, DC-Biased, AC Electric Fields
![Electrophoresis, 2005: The zeta potential of cyclo-olefin polymer microchannels and its effects on insulative (electrodeless) dielectrophoresis particle trapping devices](https://blogs.cornell.edu/kirbyresearch/wp-content/themes/gridster-lite/img/defaultthumb.png)
Electrophoresis, 2005: The zeta potential of cyclo-olefin polymer microchannels and its effects on insulative (electrodeless) dielectrophoresis particle trapping devices
![](https://blogs.cornell.edu/kirbyresearch/files/2004/06/2004_song_analyticalchemistry_thumb-2knsh9f-225x158.jpg)