Review



dfff configuration dff-30 dielectrophoretic field-flow fractionation system  (InGeneron Inc)

 
  • Logo
  • About
  • News
  • Press Release
  • Team
  • Advisors
  • Partners
  • Contact
  • Bioz Stars
  • Bioz vStars
  • 90

    Structured Review

    InGeneron Inc dfff configuration dff-30 dielectrophoretic field-flow fractionation system
    Experimental arrangement for testing toxicant detection by the <t>dFFF</t> approach that combines DEP forces with field-flow fractionation.
    Dfff Configuration Dff 30 Dielectrophoretic Field Flow Fractionation System, supplied by InGeneron Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/product/dff-30+dielectrophoretic+field-flow+fractionation+system/pmc02726257-137-2-12?v=InGeneron+Inc
    Average 90 stars, based on 1 article reviews
    dfff configuration dff-30 dielectrophoretic field-flow fractionation system - by Bioz Stars, 2026-07
    90/100 stars

    Images

    1) Product Images from "Dielectrophoretic Field-Flow Fractionation System for Detection of Aquatic Toxicants"

    Article Title: Dielectrophoretic Field-Flow Fractionation System for Detection of Aquatic Toxicants

    Journal:

    doi: 10.1021/ac801095p

    Experimental arrangement for testing toxicant detection by the dFFF approach that combines DEP forces with field-flow fractionation.
    Figure Legend Snippet: Experimental arrangement for testing toxicant detection by the dFFF approach that combines DEP forces with field-flow fractionation.

    Techniques Used: Field Flow Fractionation

    (A) dFFF chamber used for toxicological testing (B) In dFFF, the position of cells in a laminar flow stream is controlled by a balance of gravitational, DEP, and hydrodynamic lift forces causing cells to be transported at different speeds and to emerge at different times determined by their dielectric properties.
    Figure Legend Snippet: (A) dFFF chamber used for toxicological testing (B) In dFFF, the position of cells in a laminar flow stream is controlled by a balance of gravitational, DEP, and hydrodynamic lift forces causing cells to be transported at different speeds and to emerge at different times determined by their dielectric properties.

    Techniques Used:

    (A) dFFF elution profile for untreated HL-60 cells. The time of emergence of the peak, T0, was taken to represent the baseline characteristics of the cells. (B). After treatment with toxicant, in this case CCl4 at 15 mmol·L−1 for 30 min, the cell elution peak emerged at a shorter time, Tt, because of the effect of the toxicant on the membrane conductivity and capacitance. (C). dFFF elution profile for a mixture of untreated and CCl4-treated HL-60 cell culture. This was to confirm a change in elution time of treated cells. The relative change in the speed with which cells transited the chamber was taken as the measure of the response to the toxicant.
    Figure Legend Snippet: (A) dFFF elution profile for untreated HL-60 cells. The time of emergence of the peak, T0, was taken to represent the baseline characteristics of the cells. (B). After treatment with toxicant, in this case CCl4 at 15 mmol·L−1 for 30 min, the cell elution peak emerged at a shorter time, Tt, because of the effect of the toxicant on the membrane conductivity and capacitance. (C). dFFF elution profile for a mixture of untreated and CCl4-treated HL-60 cell culture. This was to confirm a change in elution time of treated cells. The relative change in the speed with which cells transited the chamber was taken as the measure of the response to the toxicant.

    Techniques Used: Membrane, Cell Culture

    Threshold sensitivity plots comparing the effectiveness of the dFFF method and viability assays. Assays lying on the isosensitivity locus have an identical sensitivity.
    Figure Legend Snippet: Threshold sensitivity plots comparing the effectiveness of the dFFF method and viability assays. Assays lying on the isosensitivity locus have an identical sensitivity.

    Techniques Used:



    Similar Products

    90
    InGeneron Inc dfff configuration dff-30 dielectrophoretic field-flow fractionation system
    Experimental arrangement for testing toxicant detection by the <t>dFFF</t> approach that combines DEP forces with field-flow fractionation.
    Dfff Configuration Dff 30 Dielectrophoretic Field Flow Fractionation System, supplied by InGeneron Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/product/dff-30+dielectrophoretic+field-flow+fractionation+system/pmc02726257-137-2-12?v=InGeneron+Inc
    Average 90 stars, based on 1 article reviews
    dfff configuration dff-30 dielectrophoretic field-flow fractionation system - by Bioz Stars, 2026-07
    90/100 stars
      Buy from Supplier

    90
    InGeneron Inc dff-30 dielectrophoretic field-flow fractionation system
    Experimental arrangement for testing toxicant detection by the <t>dFFF</t> approach that combines DEP forces with field-flow fractionation.
    Dff 30 Dielectrophoretic Field Flow Fractionation System, supplied by InGeneron Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/product/dff-30+dielectrophoretic+field-flow+fractionation+system/10__1021_slash_ac801095p-159-9-14?v=InGeneron+Inc
    Average 90 stars, based on 1 article reviews
    dff-30 dielectrophoretic field-flow fractionation system - by Bioz Stars, 2026-07
    90/100 stars
      Buy from Supplier

    Image Search Results


    Experimental arrangement for testing toxicant detection by the dFFF approach that combines DEP forces with field-flow fractionation.

    Journal:

    Article Title: Dielectrophoretic Field-Flow Fractionation System for Detection of Aquatic Toxicants

    doi: 10.1021/ac801095p

    Figure Lengend Snippet: Experimental arrangement for testing toxicant detection by the dFFF approach that combines DEP forces with field-flow fractionation.

    Article Snippet: shows the dFFF configuration, which comprised a DFF-30 dielectrophoretic field-flow fractionation system (InGeneron, Inc., Houston, TX) with a chamber, computer-controlled signal generator, and digital syringe pumps (KD Scientific) for controlling eluate flow through the chamber.

    Techniques: Field Flow Fractionation

    (A) dFFF chamber used for toxicological testing (B) In dFFF, the position of cells in a laminar flow stream is controlled by a balance of gravitational, DEP, and hydrodynamic lift forces causing cells to be transported at different speeds and to emerge at different times determined by their dielectric properties.

    Journal:

    Article Title: Dielectrophoretic Field-Flow Fractionation System for Detection of Aquatic Toxicants

    doi: 10.1021/ac801095p

    Figure Lengend Snippet: (A) dFFF chamber used for toxicological testing (B) In dFFF, the position of cells in a laminar flow stream is controlled by a balance of gravitational, DEP, and hydrodynamic lift forces causing cells to be transported at different speeds and to emerge at different times determined by their dielectric properties.

    Article Snippet: shows the dFFF configuration, which comprised a DFF-30 dielectrophoretic field-flow fractionation system (InGeneron, Inc., Houston, TX) with a chamber, computer-controlled signal generator, and digital syringe pumps (KD Scientific) for controlling eluate flow through the chamber.

    Techniques:

    (A) dFFF elution profile for untreated HL-60 cells. The time of emergence of the peak, T0, was taken to represent the baseline characteristics of the cells. (B). After treatment with toxicant, in this case CCl4 at 15 mmol·L−1 for 30 min, the cell elution peak emerged at a shorter time, Tt, because of the effect of the toxicant on the membrane conductivity and capacitance. (C). dFFF elution profile for a mixture of untreated and CCl4-treated HL-60 cell culture. This was to confirm a change in elution time of treated cells. The relative change in the speed with which cells transited the chamber was taken as the measure of the response to the toxicant.

    Journal:

    Article Title: Dielectrophoretic Field-Flow Fractionation System for Detection of Aquatic Toxicants

    doi: 10.1021/ac801095p

    Figure Lengend Snippet: (A) dFFF elution profile for untreated HL-60 cells. The time of emergence of the peak, T0, was taken to represent the baseline characteristics of the cells. (B). After treatment with toxicant, in this case CCl4 at 15 mmol·L−1 for 30 min, the cell elution peak emerged at a shorter time, Tt, because of the effect of the toxicant on the membrane conductivity and capacitance. (C). dFFF elution profile for a mixture of untreated and CCl4-treated HL-60 cell culture. This was to confirm a change in elution time of treated cells. The relative change in the speed with which cells transited the chamber was taken as the measure of the response to the toxicant.

    Article Snippet: shows the dFFF configuration, which comprised a DFF-30 dielectrophoretic field-flow fractionation system (InGeneron, Inc., Houston, TX) with a chamber, computer-controlled signal generator, and digital syringe pumps (KD Scientific) for controlling eluate flow through the chamber.

    Techniques: Membrane, Cell Culture

    Threshold sensitivity plots comparing the effectiveness of the dFFF method and viability assays. Assays lying on the isosensitivity locus have an identical sensitivity.

    Journal:

    Article Title: Dielectrophoretic Field-Flow Fractionation System for Detection of Aquatic Toxicants

    doi: 10.1021/ac801095p

    Figure Lengend Snippet: Threshold sensitivity plots comparing the effectiveness of the dFFF method and viability assays. Assays lying on the isosensitivity locus have an identical sensitivity.

    Article Snippet: shows the dFFF configuration, which comprised a DFF-30 dielectrophoretic field-flow fractionation system (InGeneron, Inc., Houston, TX) with a chamber, computer-controlled signal generator, and digital syringe pumps (KD Scientific) for controlling eluate flow through the chamber.

    Techniques: