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Review

Gradient counterflow electrophoresis methods for bioanalysis

    Chandni A Vyas

    Temple University, Dept of Chemistry, 1901 N. 13th Street, Philadelphia, PA 19122, USA.

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    Email the corresponding author at jshackman@temple.edu

    ,
    Paul M Flanigan

    Temple University, Dept of Chemistry, 1901 N. 13th Street, Philadelphia, PA 19122, USA.

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    Email the corresponding author at jshackman@temple.edu

    &
    Jonathan G Shackman

    † Author for correspondence

    Temple University, Dept of Chemistry, 1901 N. 13th Street, Philadelphia, PA 19122, USA.

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    Email the corresponding author at jshackman@temple.edu

    Published Online:13 Apr 2010https://doi.org/10.4155/bio.10.17

    Abstract

    CE has evolved as one of the most efficient separation techniques for a wide range of analytes, from small molecules to large proteins. Modern microdevices facilitate integration of multiple sample-handling steps, from preparation to separation and detection, and often rely on CE for separations. However, CE frequently requires complex geometries for performing sample injections and maintaining zone profiles across long separation lengths in microdevices. Two novel methods for performing electrophoretic separations, gradient elution moving boundary electrophoresis (GEMBE) and gradient elution isotachophoresis (GEITP), have been developed to simplify microcolumn operations. Both techniques use variable hydrodynamic counterflow and continuous sample injection to perform analyses in short, simple microcolumns. These properties result in instruments and microdevices that have minimal ‘real-world’ interfaces and reduced footprints. Additionally, GEITP is a rapid enrichment technique that addresses sensitivity issues in CE and microchips.

    Papers of special note have been highlighted as: ▪ of interest ▪▪ of considerable interest

    Bibliography

    • Vilkner T, Janasek D, Manz A. Micro total analysis systems. Recent developments. Anal. Chem.76,3373–3385 (2004).
      Medline CASGoogle Scholar
    • Dolnik V, Liu S. Applications of capillary electrophoresis on microchip. J. High Res. Chromatogr.28,1994–2009 (2005).
      CASGoogle Scholar
    • West J, Becker M, Tombrink S, Manz A. Micro total analysis systems: latest achievements. Anal. Chem.80,4403–4419 (2008).▪ Recent, comprehensive review of microfluidic instruments and applications.
      Medline CASGoogle Scholar
    • Dishinger JF, Kennedy RT. Multiplexed detection and applications for separations on parallel microchips. Electrophoresis29,3296–3305 (2008).
      Medline CASGoogle Scholar
    • Shackman JG, Munson MS, Ross D. Gradient elution moving boundary electrophoresis for high-throughput multiplexed microfluidic devices. Anal. Chem.79,565–571 (2007).
      Medline CASGoogle Scholar
    • Shackman JG, Ross D. Gradient elution isotachophoresis for enrichment and separation of biomolecules. Anal. Chem.79,6641–6649 (2007).
      Medline CASGoogle Scholar
    • Davis NI, Mamunooru M, Vyas CA, Shackman JG. Capillary and microfluidic gradient elution isotachophoresis coupled to capillary zone electrophoresis for femtomolar amino acid detection limits. Anal. Chem.81,5452–5459 (2009).
      Medline CASGoogle Scholar
    • Kostal V, Katzenmeyer J, Arriaga EA. Capillary electrophoresis in bioanalysis. Anal. Chem.80,4533–4550 (2008).
      Medline CASGoogle Scholar
    • Ross D, Romantseva EF. Gradient elution moving boundary electrophoresis with channel current detection. Anal. Chem.81,7326–7335 (2009).
      Medline CASGoogle Scholar
    • 10  Ross D, Kralj JG. Simple device for multiplexed electrophoretic separations using gradient elution moving boundary electrophoresis with channel current detection. Anal. Chem.80,9467–9474 (2008).▪▪ Novel high-throughput method for monitoring multiple enzyme reactions.
      Medline CASGoogle Scholar
    • 11  Strychalski EA, Henry AC, Ross D. Microfluidic analysis of complex samples with minimal sample preparation using gradient elution moving boundary electrophoresis. Anal. Chem.81,10201–10207 (2009).▪▪ Demonstration of minimal complex sample preparation with counterflow analysis.
      Medline CASGoogle Scholar
    • 12  Meighan MM, Keebaugh MW, Quilhuis AM, Kenyon SM, Hayes MA. Electrophoretic exclusion for the selective transport of small molecules. Electrophoresis30,3786–3792 (2009).
      Medline CASGoogle Scholar
    • 13  Hawkins KR, Yager P, Nonlinear decrease of background fluorescence in polymer thin-films – a survey of materials and how they can complicate fluorescence detection in mTAS. Lab Chip3,248–252 (2003).
      Medline CASGoogle Scholar
    • 14  Simpson SL, Quirino JP, Terabe S. On-line sample preconcentration in capillary electrophoresis: fundamentals and applications. J. Chromatogr. A1184,504–541 (2008).
      Medline CASGoogle Scholar
    • 15  Breadmore MC, Thabano JRE, Dawod M, Kazarian AA, Quirino JP, Guijt RM. Recent advances in enhancing the sensitivity of electrophoresis and electrochromatography in capillaries and microchips (2006–2008). Electrophoresis30,230–248 (2009).
      Medline CASGoogle Scholar
    • 16  Shackman JG, Ross D. Counter-flow gradient electrofocusing. Electrophoresis28,556–571 (2007).
      Medline CASGoogle Scholar
    • 17  Everaerts FM, Beckers JL, Verheggen TPEM. Isotachophoresis: Theory, Instrumentation, And Applications. Elsevier Scientific Publishing Company, Amsterdam, The Netherlands, 41–81 (1976).▪ Although somewhat dated, one of the most thorough treatments on isotachophoresis.
      Google Scholar
    • 18  Hruska V, Gas B. Kohlrausch regulating function and other conservation laws in electrophoresis. Electrophoresis28,3–14 (2007).
      Medline CASGoogle Scholar
    • 19  Khurana TK, Santiago JG. Sample zone dynamics in peak mode isotachophoresis. Anal. Chem.80,6300–6307 (2008).
      Medline CASGoogle Scholar
    • 20  Jung B, Bharadwaj R, Santiago JG. On-chip millionfold sample stacking using transient isotachophoresis. Anal. Chem.78,2319–2327 (2006).
      Medline CASGoogle Scholar
    • 21  Jung B, Zhu Y, Santiago JG. Detection of 100 aM fluorophores using a high-sensitivity on-chip CE system and transient isotachophoresis. Anal. Chem.79,345–349 (2007).
      Medline CASGoogle Scholar
    • 22  Mamunooru M, Jenkins RJ, Davis NI, Shackman JG. Gradient elution isotachophoresis with direct ultraviolet absorption detection for sensitive amino acid analysis. J. Chromatogr. A1202,203–211 (2008).
      Medline CASGoogle Scholar
    • 23  Vyas CA, Mamunooru M, Shackman JG. Amino acid measurements from a high conductivity matrix by gradient elution isotachophoresis. Chromatographia70,151–156 (2009).
      CASGoogle Scholar
    • 24  Danger G, Ross D. Chiral separation with gradient elution isotachophoresis for future in situ extraterrestrial analysis. Electrophoresis29,4036–4044 (2008).
      Medline CASGoogle Scholar
    • 25  Breadmore MC. Unlimited-volume stacking of ions in capillary electrophoresis. Part 1: stationary isotachophoretic stacking of anions. Electrophoresis29,1082–1091 (2008).
      Medline CASGoogle Scholar
    • 26  Breadmore MC, Quirino JP. 100,000-fold concentration of anions in capillary zone electrophoresis using electroosmotic flow controlled counterflow isotachophoretic stacking under field amplified conditions. Anal. Chem.80,6373–6381 (2008).
      Medline CASGoogle Scholar
    • 27  Iverson BD, Garimella SV. Recent advances in microscale pumping technologies: a review and evaluation. Microfluid. Nanofluid.5,145–174 (2008).
      CASGoogle Scholar