Protein adsorption at charged surfaces: the role of electrostatic interactions and interfacial charge regulation

Research output: Contribution to journalJournal articleResearchpeer-review

Standard

Protein adsorption at charged surfaces : the role of electrostatic interactions and interfacial charge regulation. / Hartvig, Rune A.; Van De Weert, Marco; Østergaard, Jesper; Jorgensen, Lene; Jensen, Henrik.

In: Langmuir, Vol. 27, No. 6, 15.03.2011, p. 2634-2643.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Hartvig, RA, Van De Weert, M, Østergaard, J, Jorgensen, L & Jensen, H 2011, 'Protein adsorption at charged surfaces: the role of electrostatic interactions and interfacial charge regulation', Langmuir, vol. 27, no. 6, pp. 2634-2643. https://doi.org/10.1021/la104720n

APA

Hartvig, R. A., Van De Weert, M., Østergaard, J., Jorgensen, L., & Jensen, H. (2011). Protein adsorption at charged surfaces: the role of electrostatic interactions and interfacial charge regulation. Langmuir, 27(6), 2634-2643. https://doi.org/10.1021/la104720n

Vancouver

Hartvig RA, Van De Weert M, Østergaard J, Jorgensen L, Jensen H. Protein adsorption at charged surfaces: the role of electrostatic interactions and interfacial charge regulation. Langmuir. 2011 Mar 15;27(6):2634-2643. https://doi.org/10.1021/la104720n

Author

Hartvig, Rune A. ; Van De Weert, Marco ; Østergaard, Jesper ; Jorgensen, Lene ; Jensen, Henrik. / Protein adsorption at charged surfaces : the role of electrostatic interactions and interfacial charge regulation. In: Langmuir. 2011 ; Vol. 27, No. 6. pp. 2634-2643.

Bibtex

@article{4a502ec5ed8548cc880b1c051f758eb1,
title = "Protein adsorption at charged surfaces: the role of electrostatic interactions and interfacial charge regulation",
abstract = "The understanding of protein adsorption at charged surfaces is important for a wide range of scientific disciplines including surface engineering, separation sciences and pharmaceutical sciences. Compared to chemical entities having a permanent charge, the adsorption of small ampholytes and proteins is more complicated as the pH near a charged surface can be significantly different from the value in bulk solution. In this work, we have developed a phenomenological adsorption model which takes into account the combined role of interfacial ion distribution, interfacial charge regulation of amino acids in the proximity of the surface, electroneutrality, and mass balance. The model is straightforward to apply to a given set of experimental conditions as most model parameters are obtained from bulk properties and therefore easy to estimate or are directly measurable. The model provides a detailed understanding of the importance of surface charge on adsorption and in particular of how changes in surface charge, concentration, and surface area may affect adsorption behavior. The model is successfully used to explain the experimental adsorption behavior of the two model proteins lysozyme and α-lactalbumin. It is demonstrated that it is possible to predict the pH and surface charge dependent adsorption behavior from experimental or theoretical estimates of a preferred orientation of a protein at a solid charged interface.",
author = "Hartvig, {Rune A.} and {Van De Weert}, Marco and Jesper {\O}stergaard and Lene Jorgensen and Henrik Jensen",
year = "2011",
month = "3",
day = "15",
doi = "10.1021/la104720n",
language = "English",
volume = "27",
pages = "2634--2643",
journal = "Langmuir",
issn = "0743-7463",
publisher = "American Chemical Society",
number = "6",

}

RIS

TY - JOUR

T1 - Protein adsorption at charged surfaces

T2 - the role of electrostatic interactions and interfacial charge regulation

AU - Hartvig, Rune A.

AU - Van De Weert, Marco

AU - Østergaard, Jesper

AU - Jorgensen, Lene

AU - Jensen, Henrik

PY - 2011/3/15

Y1 - 2011/3/15

N2 - The understanding of protein adsorption at charged surfaces is important for a wide range of scientific disciplines including surface engineering, separation sciences and pharmaceutical sciences. Compared to chemical entities having a permanent charge, the adsorption of small ampholytes and proteins is more complicated as the pH near a charged surface can be significantly different from the value in bulk solution. In this work, we have developed a phenomenological adsorption model which takes into account the combined role of interfacial ion distribution, interfacial charge regulation of amino acids in the proximity of the surface, electroneutrality, and mass balance. The model is straightforward to apply to a given set of experimental conditions as most model parameters are obtained from bulk properties and therefore easy to estimate or are directly measurable. The model provides a detailed understanding of the importance of surface charge on adsorption and in particular of how changes in surface charge, concentration, and surface area may affect adsorption behavior. The model is successfully used to explain the experimental adsorption behavior of the two model proteins lysozyme and α-lactalbumin. It is demonstrated that it is possible to predict the pH and surface charge dependent adsorption behavior from experimental or theoretical estimates of a preferred orientation of a protein at a solid charged interface.

AB - The understanding of protein adsorption at charged surfaces is important for a wide range of scientific disciplines including surface engineering, separation sciences and pharmaceutical sciences. Compared to chemical entities having a permanent charge, the adsorption of small ampholytes and proteins is more complicated as the pH near a charged surface can be significantly different from the value in bulk solution. In this work, we have developed a phenomenological adsorption model which takes into account the combined role of interfacial ion distribution, interfacial charge regulation of amino acids in the proximity of the surface, electroneutrality, and mass balance. The model is straightforward to apply to a given set of experimental conditions as most model parameters are obtained from bulk properties and therefore easy to estimate or are directly measurable. The model provides a detailed understanding of the importance of surface charge on adsorption and in particular of how changes in surface charge, concentration, and surface area may affect adsorption behavior. The model is successfully used to explain the experimental adsorption behavior of the two model proteins lysozyme and α-lactalbumin. It is demonstrated that it is possible to predict the pH and surface charge dependent adsorption behavior from experimental or theoretical estimates of a preferred orientation of a protein at a solid charged interface.

U2 - 10.1021/la104720n

DO - 10.1021/la104720n

M3 - Journal article

C2 - 21322572

AN - SCOPUS:79952607947

VL - 27

SP - 2634

EP - 2643

JO - Langmuir

JF - Langmuir

SN - 0743-7463

IS - 6

ER -

ID: 198779778