Aggregation of HSA, IgG, and Fibrinogen on Methylated Silicon Surfaces.

Ellipsometry was used to quantify adsorption and tapping mode atomic force microscopy to study surface aggregation of human serum albumin (HSA), immunoglobulin G (IgG), and fibrinogen (Fib) adsorbed from aqueous solutions onto methylated silicon surfaces. After exposure to air the protein monolayers were spontaneously restructured, exposing disorganized areas with heterogeneity depending on the degree of surface methylation. The aggregation patterns also depended on some properties of the adsorbed protein (such as the number of contact points with the surface), but seemed to be almost independent of the adsorption time. The results indicate that aggregates were formed due to lateral reorganization on the adsorbed layer at the air-liquid interface during the drying process. The interpretation is that the heterogeneous structures result from a thermodynamically driven interaction between the hydrophobic surface and the similarly hydrophobic air. The main conclusion that can be extracted from this work is that fibrinogen (hydrophobic and large protein) interacts more irreversibly with the silicon surfaces than IgG, and much more so than HSA, which is less hydrophobic and smaller than fibrinogen. Copyright 1998 Academic Press.

[1]  R. Varoqui,et al.  Interaction of fibrinogen with solid surfaces of varying charge and hydrophobic—hydrophilic balance: I. Adsorption isotherms , 1983 .

[2]  R. H. Dettre,et al.  Contact Angle Hysteresis. IV. Contact Angle Measurements on Heterogeneous Surfaces1 , 1965 .

[3]  W. Norde,et al.  Adsorption of proteins from solution at the solid-liquid interface. , 1986, Advances in colloid and interface science.

[4]  P. Tengvall,et al.  Molecular packing of HSA, IgG, and fibrinogen adsorbed on silicon by AFM imaging , 1998 .

[5]  P. Hansma,et al.  Direct observation of immunoglobulin adsorption dynamics using the atomic force microscope , 1990 .

[6]  P. Hansma,et al.  Scanning tunneling microscopy and atomic force microscopy: application to biology and technology. , 1988, Science.

[7]  Arunan Nadarajah,et al.  A Comprehensive Model of Multiprotein Adsorption on Surfaces , 1994 .

[8]  J. Andrade,et al.  Plasma Protein Adsorption: The Big Twelve a , 1987, Annals of the New York Academy of Sciences.

[9]  I. Lundström,et al.  Simple kinetic models for protein exchange reactions on solid surfaces , 1990 .

[10]  W. Zisman,et al.  Contact angle, wettability, and adhesion , 1964 .

[11]  A. Sadana Protein adsorption and inactivation on surfaces. Influence of heterogeneities , 1992 .

[12]  H. Nygren,et al.  Molecular and supramolecular structure of adsorbed fibrinogen and adsorption isotherms of fibrinogen at quartz surfaces. , 1988, Journal of biomedical materials research.

[13]  C. Lowe,et al.  AFM Studies of Protein Adsorption , 1994 .

[14]  R. Erlandsson,et al.  A scanning force microscope designed for applied surface studies , 1990 .

[15]  I. Lundström,et al.  Structure of adsorbed fibrinogen obtained by scanning force microscopy , 1991, FEBS letters.

[16]  D. K. Chattoraj,et al.  Protein adsorption at solid-liquid interfaces: Part I--Affinities of proteins for alumina surface. , 1991, Indian journal of biochemistry & biophysics.

[17]  I. Lundström,et al.  Adsorption behavior of fibronectin on well-characterized silica surfaces , 1982 .

[18]  J. M. Peula,et al.  Adsorption of monomeric bovine serum albumin on sulfonated polystyrene model colloids 3. Colloidal stability of latex—protein complexes , 1994 .

[19]  R. H. Dettre,et al.  Contact Angle Hysteresis: I. Study of an Idealized Rough Surface , 1964 .

[20]  H. Busscher,et al.  Patchwise character of fibronectin films adsorbed on biomaterials with different surface free energies; the influence of protein concentration, adsorption time, shear rate and pH , 1991 .