Published April 29, 2025 | Version v1
Journal article Open

Assessment of Electrophoretic Mobility Determination in Nanoparticle Analysis: Two Parallel Techniques Converging in a Distinctive Parameter

Authors/Creators

  • 1. VITO
  • 2. ROR icon Ghent University
  • 3. ROR icon Flemish Institute for Technological Research

Files

Electrophoresis - 2025 - Adelantado - Assessment of Electrophoretic Mobility Determination in Nanoparticle Analysis Two.pdf

Files (817.1 kB)

Additional details

Identifiers

DOI
10.1002/elps.202400132

Related works

Is original form of
Journal article: 10.1002/elps.202400132 (DOI)

Funding

European Commission
CE4Plastics - Capillary electrophoresis as a main pillar for the characterisation of nanoplastics released from single-use and reusable plastic drinking bottles 101059423

Dates

Available
2025-04-29

References

  • S. Štěpánová and V. Kašička, "Determination of Physicochemical Parameters of (Bio)molecules and (Bio)particles by Capillary Electromigration Methods," Journal of Separation Science 47 (2024): 2400174
  • B. Xiong, A. Pallandre, I. Le Potier, P. Audebert, E. Fattal, N. Tsapis, et al., "Electrophoretic Mobility Measurement by Laser Doppler Velocimetry and Capillary Electrophoresis of Micrometric Fluorescent Polystyrene Beads," Analytical Methods 4 (2012): 183–189
  • G. Elliott and T. Beutner, "Molecular Filter Based Planar Doppler Velocimetry," Progress in Aerospace Sciences 35 (1999): 799–845
  • F. Oukacine, A. Morel, and H. Cottet, "Characterization of Carboxylated Nanolatexes by Capillary Electrophoresis," Langmuir 27 (2011): 4040–4047
  • G. Ramírez-Garcíad, F. Orlyé, S. Gutiérrez-Granados, et al., "Functionalization and Characterization of Persistent Luminescence Nanoparticles by Dynamic Light Scattering, Laser Doppler and Capillary Electrophoresis," Colloids and Surfaces B 136 (2015): 272–281
  • N. Vanifatova, B. Spivakov, and A. Kamyshny, "Comparison of Potential of Capillary Zone Electrophoresis and Malvern's Improved Laser Doppler Velocimetry for Characterisation of Silica Nanomaterials in Aqueous Media," International Journal of Nanoparticles 4, no. 4 (2011): 369–380
  • S. Bu, M. Sonker, D. Koh, and A. Ros, "On the Behavior of Sub-Micrometer Polystyrene Particles Subjected to AC Insulator-Based Dielectrophoresis," Electrophoresis 45 (2024): 1065–1079
  • K. Zhao, J. Yao, Y. Wei, D. Kong, and J. Wang, "Numerical Studies of Manipulation and Separation of Microparticles in ODEP-Based Microfluidic Chips," Electrophoresis 45 (2024): 1–10
  • V. Dosedělová and P. Kubáň, "Investigation of Interactions Between Biological Thiols and Gold Nanoparticles by Capillary Electrophoresis With Laser-Induced Fluorescence," Electrophoresis 45 (2024): 1–10
  • L. Oliveira, M. Arroyave, M. Pistonesi, W. Fragoso, and V. Springer, "Capillary Electrophoresis Coupled to Chemometrics for Analysis of Carbon Dots in Nanoparticles Mixtures," Electrophoresis 43 (2022): 901–908
  • R. A. Frazier, J. M. Ames, and H. E. Nursten, Capillary Electrophoresis for Food Analysis: Method Development (Cambridge University Press, 2007)
  • C. Adelantado, B. H. Lapizco-Encinas, J. Jordens, S. Voorspoels, M. Velimirovic, and K. Tirez, "Capillary Electrophoresis as a Complementary Analytical Tool for the Separation and Detection of Nanoplastic Particles," Analytical Chemistry 96 (2024): 7706–7713
  • V. Šolínová and V. Kašička, "Determination of Acidity Constants and Ionic Mobilities of Polyprotic Peptide Hormones by CZE," Electrophoresis 34 (2013): 2655–2665
  • D. Koval, V. Kašička, J. Jiráček, and M. Collinsová, "Physicochemical Characterization of Phosphinic Pseudopeptides by Capillary Zone Electrophoresis in Highly Acidic Background Electrolytes," Electrophoresis 24 (2003): 774–781
  • C. Evenhuis, V. Hruska, R. Guijt, et al., "Reliable Electrophoretic Mobilities Free From Joule Heating Effects Using CE," Electrophoresis 28 (2007): 3759–3766
  • Z. Wang, W. Hsu, S. Tsuchiya, S. Paul, A. Alizadeh, and H. Daiguji, "Joule Heating Effects on Transport-Induced-Charge Phenomena in an Ultrathin Nanopore," Micromachines 11 (2020): 1–12
  • K. Danov and P. Kralchevsky, "Forces Acting on Dielectric Colloidal Spheres at a Water/Nonpolar Fluid Interface in an External Electric Field. 2. Charged Particles," Journal of Colloid & Interface Science 405 (2013): 269–277
  • H. Zhao and H. Bau, "Effect of Double-Layer Polarization on the Forces That Act on a Nanosized Cylindrical Particle in an AC Electrical Field," Langmuir 24 (2008): 6050–6059
  • S. Ehala, J. Dybal, E. Makrík, and V. Kašička, "Capillary Affinity Electrophoresis and Abinitio Calculation Studies of Valinomycin Complexation With Na+ Ion," Journal of Separation Science 32 (2009): 597–604
  • C. Zhao and C. Yang, "Joule Heating Induced Heat Transfer for Electroosmotic Flow of Power-law Fluids in a Microcapillary," International Journal of Heat & Mass Transfer 55 (2012): 2044–2051
  • A. Rathore, K. Reynolds, and L. Colón, "Joule Heating in Packed Capillaries Used in Capillary Electrochromatography," Electrophoresis 23 (2002): 2918–2928
  • J. Hsu, Y. Tai, and L. Yeh, "Importance of Temperature Effect on the Electrophoretic Behavior of Charge-Regulated Particles," Langmuir 28 (2012): 1013–1019
  • R. O'Brien and L. White, "Electrophoretic Mobility of a Spherical Colloidal Particle," The Royal Society of Chemistry 74 (1978): 1607–1626
  • H. Falahati, L. Wong, L. Davarpanah, A. Garg, P. Schmitz, and D. Barz, "The Zeta Potential of PMMA in Contact With Electrolytes of Various Conditions: Theoretical and Experimental Investigation," Electrophoresis 35 (2014): 870–882
  • S. Tseng, J. Lin, and J. Hsu, "Theoretical Study of Temperature Influence on the Electrophoresis of a pH-Regulated Polyelectrolyte," Analytica Chimica Acta 847 (2014): 80–89
  • V. Shilov, A. Delgado, F. González-Caballero, J. Horno, J. López-García, and C. Grosse, "Polarization of the Electrical Double Layer. Time Evolution After Application of an Electric Field," Journal of Colloid & Interface Science 232 (2000): 141–148
  • Z. Kučerova, M. Szumski, B. Buszewski, and P. Jandera, "Alkylated Poly(styrene-divinylbenzene) Monolithic Columns for µ-HPLC and CEC Separation of Phenolic Acids," Journal of Separation Science 30 (2007): 3018–3026
  • B. B. Vanoman and G. L. Mcintire, "Analytical Separation of Polystyrene Nanospheres by Capillary Electrophoresis," Journal of Microcolumn Separations 1 (1989): 289–293
  • N. Anik, M. Airiau, M. Labeau, W. Bzducha, and H. Cottet, "Characterization of Copolymer Latexes by Capillary Electrophoresis," Langmuir 26 (2010): 1700–1706
  • M. Mori, W. Hu, P. Haddad, et al., "Capillary Electrophoresis Using High Ionic Strength Background Electrolytes Containing Zwitterionic and Non-Ionic Surfactants and Its Application to Direct Determination of Bromide and Nitrate in Seawater," Analytical Bioanalytical Chemistry 372 (2002): 181–186
  • E. Little and J. Foley, "Optimization of the Resolution of PTH-amino Acids Through Control of Surfactant Concentration in Micellar Electrokinetic Capillary Chromatography: SDS vs. brij 35/SDS Micellar Systems," Journal of Microcolumn Separations 4 (1992): 145–154
  • Y. R. Shi, M. P. Ye, L. C. Du, and Y. X. Weng, "Experimental Determination of Particle Size-Dependent Surface Charge Density for Silica Nanospheres," Journal of Physical Chemistry C 122 (2018): 23764–23771
  • A. Filippov and V. Starov, "Interaction of Nanoparticles in Electrolyte Solutions," Journal of Physical Chemistry B 127 (2023): 6562–6572
  • Z. Abbas, C. Labbez, S. Nordholm, and E. Ahlberg, "Size-dependent Surface Charging of Nanoparticles," Journal of Physical Chemistry C 112 (2008): 5715–5723
  • E. Rideal, "The Physics and Chemistry of Surfaces," Nature 8 (1931): 2156
  • D. Matyushov, "Electrophoretic Mobility of Nanoparticles in Water," Journal of Physical Chemistry B 128 (2024): 2930–2938
  • W. Kok, Capillary Electrophoresis: Instrumentation and Operation, (Springer, 2000)
  • M. Jaros, V. Hruska, M. Stedry, I. Zuskova, and B. Gas, "Eigenmobilities in Background Electrolytes for Capillary Zone Electrophoresis: IV. Computer Program PeakMaster," Electrophoresis 25, no. 18–19 (2004): 3080–3085
  • H. Ohshima, "A Simple Expression for Henry's Function for the Retardation Effect in Electrophoresis of Spherical Colloidal Particles," Journal of Colloid & Interface Science 168 (1994): 269–271
  • M. Cabuk, M. Yavuz, and H. I. Unal, "Electrokinetic Properties of Biodegradable Conducting Polyaniline-Graft-Chitosan Copolymer in Aqueous and Non-Aqueous Media," Colloids and Surfaces A 460 (2014): 494–501
  • A. S. Dukhin and R. Xu, " Zeta-Potential Measurements," in Characterization of Nanoparticles: Measurement Processes for Nanoparticles, eds. V.-D. Hodoroaba, W. E. S. Unger, A. G. Shard (Elsevier, 2019), 213–224