QCM-D Study of E-casein Adsorption on Bimodal PEG Brushes
Adsorption of proteins onto a solid surface is believed to be the initial and controlling step in biofouling. A better knowledge of the fouling process can be obtained by controlling the formation of the first protein layer at a solid surface. A number of methods have been investigated to inhibit adsorption of proteins. In this study, the adsorption kinetics of
[1] J.Visser and T.J.M.Jeurnink, "Fouling of heat exchangers in the dairy
industry," Experimental Thermal and Fluid Science, vol. 14, pp. 407-
424, 1997.
[2] J. Wei, D.B. Ravn, L. Gram and P. Kingshott, "Stainless steel modified
with PEG can prevent protein adsorption but not bacterial adhesion",
Colloids and Surfaces B: Biointerfaces, vol. 32, pp. 275-291.2005.
[3] R.Fukai. P.H.R.Dakwa and W.Chen, "Strategies toward biocompatible
artificial implants:grafting of functionalized poly(ethylene glycol)s to
poly(ethylene terephthalate) surfaces", Journal of Polymer Science:Part
A:Polymer Chemistry. vol. 42, pp. 5389-5400, 2004.
[4] P. Kingshott, W. Jiang, G. B. Nikolaj and G. Lone, G, "Covalent
attachment of poly(ethylene glycol) to surfaces, critical for reducing
bacterial adhesion", Langmuir. vol. 19, pp. 6912-6921, 2003 .
[5] L.D.Unsworth, H.Sheardown and J.L.Brash, "Protein resistance of
surfaces prepared by sorption of end-thiolated poly(ethylene glycol) to
gold:Effect of surface chain density", Langmuir. vol. 21. pp.1036-1041,
2005 .
[6] T.Satomi, Y.Nagasaki, H.Kobayashi, T.Tateishi, K.Kataoka and
H.Otsuka, "Physicochemical characterization of densely packed poly
(ethylene glycol) layer for minimizing nonspecific protein adsorption",
Journal of Nanoscience and Nanotechnology, vol. 7, pp. 2394-2399,
2007.
[7] J.G. Archambault and J.L. Brash, "Protein repellent polyurethane-urea
surfaces by chemical grafting of hydroxyl-terminated poly(ethylene
oxide): Effects of protein size and charge", Colloids and Surfaces B:
Biointerfaces, vol. 33, pp. 111-120, 2004.
[8] A. Roosjen, H.C. Mei, H.J. Busscher and W. Norde, "Microbial
adhesion to poly(ethylene oxide) brushes: Influence of polymer chain
length and temperature", Langmuir, vol. 20, pp. 10949-10955, 2004.
[9] W.Norde and D.Gage, "Interaction of BSA and human blood plasma
with PEO-tethered surfaces: Influence of PEO chain length, grafting
density and temperature", Langmuir, vol. 20, pp. 4162-4167, 2004.
[10] K.L.Prime and G.M.Whitesides, "Adsorption of proteins onto surfaces
containing end-attached oligo( ethylene oxide): A model system using
self-assembled monolayers", Journal American Chemistry Society, vol.
115, pp. 10714-10721, 1993.
[11] K.Uchida, H.Otsuka, M.Kaneko, K.Kataoka and Y.Nagasaki, "A
reactive poly (ethylene glycol) layer to achieve specific surface plasmon
resonance sensing with a high S/N: The substantial role of a short
underbrushed PEG layer in minimizing nonspecific adsorption",
Analytical Chemistry, vol. 77, pp. 1075-1080. 2005.
[12] C.Yoshikawa, A.Goto. Y.Tsuji, T.Fukuda, T.Kimura, K.Yamamoto and
A.Kishida, "Protein repellency of well-defined, concentrated poly (2-
hydroxyethyl methacrylate) brushes by the size exclusion effect",
Macromolecules, vol. 39, pp. 2284-2290, 2006.
[13] Y.J.Wu, R.B.Timmons, J.S.Jen and F.E.Molock, "Non-fouling surfaces
produced by gas phase pulsed plasma polymerization of an ultra low
molecular weight ethylene oxide containing monomer", Colloids and
surfaces B: Biointerfaces, vol. 18, pp. 235-248, 2000.
[14] A.Helparin, "Polymer brushes that resist adsorption of model
proteins:Design parameters", Langmuir, vol. 15, pp. 2525-2533, 1999.
[15] K. Uchida, Y. Hoshino, A. Tamura, K.Yoshimoto S. Kojima,
K.Yamashita, I. Ymanaka, H. Otsuka, K. Kataoka and Y.Nagasaki,
"Creation of a mixed poly(ethylene glycol) tethered-chain surface for
preventing the nonspecific adsorption of proteins and peptides,"
Biointerphases, vol. 2, pp. 126-130, 2007.
[16] M.Rodahl, F.Hook, C.Fredriksson, C.A. Keller, A.Krozer, P.Brzezinski,
M.Voinova and B.Kasemo, "Simultaneous frequency and dissipation
factor QCM measurements of biomolecular adsorption and cell
adhesion", Faraday Discuss, vol. 107, pp. 229-246, 1997.
[17] F. Hook, J. Voros, M. Rodahl, R. Kurrat, P. Boni, J.J. Ramsden, M.
Textor, N.D. Spencer, P. Tengvall, J. Gold and B. Kasemo, "A
comparative study of protein adsorption on titanium oxide sSurfaces
using in situ Ellipsometry, Optical Waveguide Lightmode Spectroscopy
and Quartz Crystal Microbalance/Dissipation". Colloids and Surfaces
B: Biointerfaces, pp. 155-170, 2002.
[18] M.T. Muller, X. Yan, S. Lee, S.S. Perry and N.D. Spencer, N.D. (2005).
"Lubrication properties of a brushlike copolymer as a function of the
amount of solvent absorbed within the brush". Macromolecules, pp.
5706-5713, 2005.
[19] M.Lee, S.K.Park, C.Chung and H.Kim, "QCM study of beta-casein
adsorption on the hydrophobic surface: Effect of ionic strength and
cations", Bulletin of the Korean Chemical Society, vol. 25, pp. 1031-
1035, 2004.
[20] N.Nath, J.Hyun, H.Ma and A.Chilkoti, "Surface Engineering for Control
of Protein and Cell Interactions", Surface Science, vol. 570, pp. 98-110,
2004.
[21] M.Jonsson and H.O. Johansson, "Effect of surface grafted polymers on
the adsorption of different model proteins", Colloids and Surfaces B:
Biointerfaces, vol. 37, pp.71-81, 2004.
[22] M.A.Carignano and I.Szleifer. 2000, "Prevention of protein adsorption
by flexible and rigid chain molecules", Colloids and Surfaces B:
Biointerfaces, vol. 18, pp. 169-182, 2000.
[23] L.D. Unsworth, H. Sheardown and J.L. Brash, "Protein resistance of
surfaces prepared by sorption of end-thiolated poly (ethylene glycol) to
gold: Effect of surface chain density", Langmuir, vol. 21, pp. 1036-1041,
2005.
[24] P.Y. J.Yeh, R. K. Kainthan, Y. Zou, M. Chiao and J. N. Kizhakkedathu,
Self-assembled monothiol-terminated yyperbranched polyglycerols on a
gold surface: A comparative study on the structure, morphology, and
protein adsorption characteristics with linear poly(ethylene
glycol)s,"Langmuir, vol. 24, pp. 4907-4916, 2008.
[25] L.D.Unsworth, Z.Tun, H.Sheardown and J.L.Brash, "In situ neutron
relectrometry investigation of gold-chemisorbed PEO layers of varying
chain density: Relationship of layer structure to protein resistance,"
Journal of Colloid and Interface Science, vol. 296, pp.520-526, 2008.
[26] M.Malmsten, K.Emoto and J.M.V.Alstine, "Effect of chain density on
inhibition of protein adsorption by Poly(ethylene glycol) based
coatings", Journal of Colloidal and Interface Science, vol. 202, pp. 507-
517, 1998.
[1] J.Visser and T.J.M.Jeurnink, "Fouling of heat exchangers in the dairy
industry," Experimental Thermal and Fluid Science, vol. 14, pp. 407-
424, 1997.
[2] J. Wei, D.B. Ravn, L. Gram and P. Kingshott, "Stainless steel modified
with PEG can prevent protein adsorption but not bacterial adhesion",
Colloids and Surfaces B: Biointerfaces, vol. 32, pp. 275-291.2005.
[3] R.Fukai. P.H.R.Dakwa and W.Chen, "Strategies toward biocompatible
artificial implants:grafting of functionalized poly(ethylene glycol)s to
poly(ethylene terephthalate) surfaces", Journal of Polymer Science:Part
A:Polymer Chemistry. vol. 42, pp. 5389-5400, 2004.
[4] P. Kingshott, W. Jiang, G. B. Nikolaj and G. Lone, G, "Covalent
attachment of poly(ethylene glycol) to surfaces, critical for reducing
bacterial adhesion", Langmuir. vol. 19, pp. 6912-6921, 2003 .
[5] L.D.Unsworth, H.Sheardown and J.L.Brash, "Protein resistance of
surfaces prepared by sorption of end-thiolated poly(ethylene glycol) to
gold:Effect of surface chain density", Langmuir. vol. 21. pp.1036-1041,
2005 .
[6] T.Satomi, Y.Nagasaki, H.Kobayashi, T.Tateishi, K.Kataoka and
H.Otsuka, "Physicochemical characterization of densely packed poly
(ethylene glycol) layer for minimizing nonspecific protein adsorption",
Journal of Nanoscience and Nanotechnology, vol. 7, pp. 2394-2399,
2007.
[7] J.G. Archambault and J.L. Brash, "Protein repellent polyurethane-urea
surfaces by chemical grafting of hydroxyl-terminated poly(ethylene
oxide): Effects of protein size and charge", Colloids and Surfaces B:
Biointerfaces, vol. 33, pp. 111-120, 2004.
[8] A. Roosjen, H.C. Mei, H.J. Busscher and W. Norde, "Microbial
adhesion to poly(ethylene oxide) brushes: Influence of polymer chain
length and temperature", Langmuir, vol. 20, pp. 10949-10955, 2004.
[9] W.Norde and D.Gage, "Interaction of BSA and human blood plasma
with PEO-tethered surfaces: Influence of PEO chain length, grafting
density and temperature", Langmuir, vol. 20, pp. 4162-4167, 2004.
[10] K.L.Prime and G.M.Whitesides, "Adsorption of proteins onto surfaces
containing end-attached oligo( ethylene oxide): A model system using
self-assembled monolayers", Journal American Chemistry Society, vol.
115, pp. 10714-10721, 1993.
[11] K.Uchida, H.Otsuka, M.Kaneko, K.Kataoka and Y.Nagasaki, "A
reactive poly (ethylene glycol) layer to achieve specific surface plasmon
resonance sensing with a high S/N: The substantial role of a short
underbrushed PEG layer in minimizing nonspecific adsorption",
Analytical Chemistry, vol. 77, pp. 1075-1080. 2005.
[12] C.Yoshikawa, A.Goto. Y.Tsuji, T.Fukuda, T.Kimura, K.Yamamoto and
A.Kishida, "Protein repellency of well-defined, concentrated poly (2-
hydroxyethyl methacrylate) brushes by the size exclusion effect",
Macromolecules, vol. 39, pp. 2284-2290, 2006.
[13] Y.J.Wu, R.B.Timmons, J.S.Jen and F.E.Molock, "Non-fouling surfaces
produced by gas phase pulsed plasma polymerization of an ultra low
molecular weight ethylene oxide containing monomer", Colloids and
surfaces B: Biointerfaces, vol. 18, pp. 235-248, 2000.
[14] A.Helparin, "Polymer brushes that resist adsorption of model
proteins:Design parameters", Langmuir, vol. 15, pp. 2525-2533, 1999.
[15] K. Uchida, Y. Hoshino, A. Tamura, K.Yoshimoto S. Kojima,
K.Yamashita, I. Ymanaka, H. Otsuka, K. Kataoka and Y.Nagasaki,
"Creation of a mixed poly(ethylene glycol) tethered-chain surface for
preventing the nonspecific adsorption of proteins and peptides,"
Biointerphases, vol. 2, pp. 126-130, 2007.
[16] M.Rodahl, F.Hook, C.Fredriksson, C.A. Keller, A.Krozer, P.Brzezinski,
M.Voinova and B.Kasemo, "Simultaneous frequency and dissipation
factor QCM measurements of biomolecular adsorption and cell
adhesion", Faraday Discuss, vol. 107, pp. 229-246, 1997.
[17] F. Hook, J. Voros, M. Rodahl, R. Kurrat, P. Boni, J.J. Ramsden, M.
Textor, N.D. Spencer, P. Tengvall, J. Gold and B. Kasemo, "A
comparative study of protein adsorption on titanium oxide sSurfaces
using in situ Ellipsometry, Optical Waveguide Lightmode Spectroscopy
and Quartz Crystal Microbalance/Dissipation". Colloids and Surfaces
B: Biointerfaces, pp. 155-170, 2002.
[18] M.T. Muller, X. Yan, S. Lee, S.S. Perry and N.D. Spencer, N.D. (2005).
"Lubrication properties of a brushlike copolymer as a function of the
amount of solvent absorbed within the brush". Macromolecules, pp.
5706-5713, 2005.
[19] M.Lee, S.K.Park, C.Chung and H.Kim, "QCM study of beta-casein
adsorption on the hydrophobic surface: Effect of ionic strength and
cations", Bulletin of the Korean Chemical Society, vol. 25, pp. 1031-
1035, 2004.
[20] N.Nath, J.Hyun, H.Ma and A.Chilkoti, "Surface Engineering for Control
of Protein and Cell Interactions", Surface Science, vol. 570, pp. 98-110,
2004.
[21] M.Jonsson and H.O. Johansson, "Effect of surface grafted polymers on
the adsorption of different model proteins", Colloids and Surfaces B:
Biointerfaces, vol. 37, pp.71-81, 2004.
[22] M.A.Carignano and I.Szleifer. 2000, "Prevention of protein adsorption
by flexible and rigid chain molecules", Colloids and Surfaces B:
Biointerfaces, vol. 18, pp. 169-182, 2000.
[23] L.D. Unsworth, H. Sheardown and J.L. Brash, "Protein resistance of
surfaces prepared by sorption of end-thiolated poly (ethylene glycol) to
gold: Effect of surface chain density", Langmuir, vol. 21, pp. 1036-1041,
2005.
[24] P.Y. J.Yeh, R. K. Kainthan, Y. Zou, M. Chiao and J. N. Kizhakkedathu,
Self-assembled monothiol-terminated yyperbranched polyglycerols on a
gold surface: A comparative study on the structure, morphology, and
protein adsorption characteristics with linear poly(ethylene
glycol)s,"Langmuir, vol. 24, pp. 4907-4916, 2008.
[25] L.D.Unsworth, Z.Tun, H.Sheardown and J.L.Brash, "In situ neutron
relectrometry investigation of gold-chemisorbed PEO layers of varying
chain density: Relationship of layer structure to protein resistance,"
Journal of Colloid and Interface Science, vol. 296, pp.520-526, 2008.
[26] M.Malmsten, K.Emoto and J.M.V.Alstine, "Effect of chain density on
inhibition of protein adsorption by Poly(ethylene glycol) based
coatings", Journal of Colloidal and Interface Science, vol. 202, pp. 507-
517, 1998.
@article{"International Journal of Chemical, Materials and Biomolecular Sciences:64639", author = "N. Ngadi and J. Abrahamson and C. Fee and K. Morison", title = "QCM-D Study of E-casein Adsorption on Bimodal PEG Brushes ", abstract = "Adsorption of proteins onto a solid surface is believed to be the initial and controlling step in biofouling. A better knowledge of the fouling process can be obtained by controlling the formation of the first protein layer at a solid surface. A number of methods have been investigated to inhibit adsorption of proteins. In this study, the adsorption kinetics of
", keywords = "E-casein, QCM-D, stainless steel, bimodal brush,
PEG ", volume = "3", number = "3", pages = "197-6", }
