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Physicochemical properties of bovine plasma fibrinogen (Fb) in electrolyte solutions were characterised, comprising the diffusion coefficient (hydrodynamic radius), electrophoretic mobility (zeta potential) and the isoelectric point, found to be at pH=5.8. Similar electrokinetic measurements were performed for the mica substrate using the streaming potential cell. The kinetics of Fb adsorption on mica under diffusion-controlled transport was also studied. The surface concentration of Fb on mica was determined directly by AFM counting. By adjusting the time of adsorption, and bulk Fb concentration, monolayers of desired coverage were produced. It was confirmed that Fb adsorbed irreversibly on mica both at pH=3.5 and pH=7.4 (physiological value). It was postulated that in the latter case, where both the substrate and fibrinogen molecules were negatively charged, adsorption was due to heterogeneous charge distribution over the protein molecule. In order to check this hypothesis, monolayers of Fb on mica were studied using the colloid enhancement (CE) method, in which negatively and positively charged latex particles were used. Results of these experiments were quantitatively interpreted in terms of the fluctuation theory assuming that adsorption sites consisted of two and three Fb molecules, for pH=3.5 and 7.4, respectively. This allowed one to determine limits of applicability of the classical DLVO theory and confirm a heterogeneous charge distribution over the Fb molecule. It was also concluded that the CE method can be used for a sensitive determination of the Fb bulk concentration for the range inaccessible for other methods, i.e., for 0.1ppm and below. Another effect of vital significance confirmed in this work was that for some range of fibrinogen coverage both the negative and positive latexes efficiently adsorbed. This indicates the formation of superadsorbing surfaces having potential significance for various filtration processes.
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1--11
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Bibliogr. 29 poz., rys., tab., wykr.
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autor
autor
autor
- J. Haber Institute of Catalysis and Surface Chemistry, Polish Academy of Sciences, ul. Niezapominajek 8, 30-239 Cracow, Poland, Phone: 0048 12 6395104; Fax: 0048 12 425923, ncnattic@cyf-kr.edu.pl
Bibliografia
- Adamczyk, Z. 2000. Kinetics of diffusion-controlled adsorption of colloid particles and proteins. Journal of Colloid and Interface Science 220: 477-489.
- Adamczyk, Z. 2006. Particles at Interfaces: Interactions, Deposition, Structure. Academic Press, Elsevier.
- Adamczyk, Z., J. Barbasz, M. Cieśla. 2010a. Kinetics of fibrinogen adsorption on hydrophilic substrates. Langmuir 26: 11934-11945.
- Adamczyk, Z., A. Michna, M. Szaraniec, A. Bratek, J. Barbasz. 2007. Characterization of poly(ethylene imine) layers on mica by the streaming potential and particle deposition methods. Journal of Colloid and Interface Science 313: 86-96.
- Adamczyk, Z., M. Nattich, M. Wasilewska. 2010b. Irreversible adsorption of latex particles on fibrinogen covered mica. Adsorption 16: 259-269.
- Adamczyk, Z., B. Senger, J.C. Voegel, P. Schaaf. 1999a. Irreversible adsorption/deposition kinetics: A generalized approach. Journal of Chemical Physics 110: 3118-3128.
- Adamczyk, Z., P. Warszyński, M. Zembala. 1999b. Influence of adsorbed colloid particles on streaming potential. Bulletin of the Polish Academy of Sciences: Chemistry 47: 239-258.
- Adamczyk, Z., M. Zaucha, M. Zembala. 2010c. Zeta potential of mica covered by colloid particles: A streaming potential study. Langmuir 26: 9368-9377.
- Adamczyk, Z., M. Zembala, A. Michna. 2006. Polyelectrolyte adsorption layers studied by streaming potential and particle deposition. Journal of Colloid and Interface Science 303: 353-364.
- Buijs, J., P.A.W. van den Berg, J.W.Th. Lichtenbelt, W. Norde, J. Lyklema. 1996. Adsorption dynamics of IgG and its F(ab’)2 and Fc fragments studied by reflectometry. Journal of Colloid and Interface Science 178: 594-605.
- Buijs, J., D.D. White, W. Norde. 1997. The effect of adsorption on the antigen binding by IgG and its F(ab’)2 fragments. Colloids and Surfaces B Biointerfaces 8: 239-249.
- Choi, K.H., J.M. Friedt, F. Frederix, A. Campitelli, G. Borghs. 2002. Simultaneous atomic force microscope and quartz crystal microbalance measurements: Investigation of human plasma fibrinogen adsorption. Applied Physics Letters 81: 1335-1337.
- Hall, C.E., H.S.J. Slayter. 1959. The fibrinogen molecule: its size, shape, and mode of polymerization. The Journal of Biophysical and Biochemical Cytology 5: 11-18.
- Hayes, R.A., M.R. Biehmer, L.G.J. Fokkink. 1999. A study of silica nanoparticle adsorption using optical reflectometry and streaming potential techniques. Langmuir 15: 2865-2870.
- Jin, X., N.H.L. Wang, G. Tarjus, J. Talbot. 1993. Irreversible adsorption on nonuniform surfaces: the random site model. Journal of Physical Chemistry 97: 4256-4258.
- Melmsten, M. 1994. Ellipsometry studies of protein layers adsorbed at hydrophobic surfaces. Journal of Colloid and Interface Science 166: 333-342.
- Ramsden, J.J. 1993. Experimental methods for investigating protein adsorption kinetics at surfaces. Quarterly Reviews of Biophysics 27: 41-105.
- Reisch, A., J.C. Voegel, E. Gonthier, G. Decher, B. Senger, P. Schaaf, P.J. Mésini. 2009. Polyelectrolyte multilayers capped with polyelectrolytes bearing phosphorylcholine and triethylene glycol groups: parameters influencing antifouling properties. Langmuir 25: 3610-3617.
- Schaaf, P., J. Talbot. 1989. Surface exclusion effects in adsorption processes. Journal of Chemical Physics 91: 4401-4409.
- Toscano, A., M.M. Santore. 2006. Fibrinogen adsorption on three silica-based surfaces: conformation and kinetics. Langmuir 22: 2588-2597.
- Vasina, E.N., P. Dejardin. 2004. Adsorption of a-chymotrypsin onto mica in laminar flow conditions. Adsorption kinetic constant as a function of tris buffer concentration at pH 8.6. Langmuir 20: 8699-8706.
- Wasilewska, M., Z. Adamczyk. 2011. Fibrinogen adsorption on mica studied by AFM and in situ streaming potential measurements. Langmuir 27: 686-696.
- Wasilewska, M., Z. Adamczyk, B. Jachimska. 2009. Structure of fibrinogen in electrolyte solutions derived from dynamic light scattering (DLS) and viscosity measurements. Langmuir 25: 3698-3704.
- Wertz, Ch.F., M.M. Santore. 2001. Fibrinogen adsorption on hydrophilic and hydrophobic surfaces: geometrical and energetic aspects of interfacial relaxations. Langmuir 17: 3006-3016.
- Zembala, M., Z. Adamczyk. 2000. Measurements of streaming potential for mica covered by colloid particles. Langmuir 16: 1593-1601.
- Zembala, M., Z. Adamczyk, P. Warszyƒski. 2003. Streaming potential of mica covered by latex particles. Colloids and Surfaces A 222: 329-339.
- Zembala, M., P. Dejardin. 1994. Streaming potential measurements related to fibrinogen adsorption onto silica capillaries. Colloids and Surfaces B 3: 119-129.
- Zembala, M., J.C. Voegel, P. Schaaf. 1998. Elution process of adsorbed fibrinogen by SDS: competition between removal and anchoring. Langmuir 14: 2167-2173.
- Yoon, J.Y., H.Y. Park, J.H. Kim, W.S. Kim. 1996. Adsorption of BSA on highly carboxylated microspheres - quantitative effects of surface functional groups and interaction forces. Journal of Colloid and Interface Science 177: 613-620.
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Bibliografia
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