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by Keyword: Conformational-changes


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Pegueroles, M., Tonda-Turo, C., Planell, J. A., Gil, F. J., Aparicio, C., (2012). Adsorption of fibronectin, fibrinogen, and albumin on TiO2: Time-resolved kinetics, structural changes, and competition study Biointerphases , 7, (48), 13

An understanding of protein adsorption process is crucial for designing biomaterial surfaces. In this work, with the use of a quartz-crystal microbalance with dissipation monitoring, we researched the following: (a) the kinetics of adsorption on TiO2 surfaces of three extensively described proteins that are relevant for metallic implant integration [i.e., albumin (BSA), fibrinogen (Fbg), and fibronectin (Fn)]; and (b) the competition of those proteins for adsorbing on TiO2 in a two-step experiment consisted of sequentially exposing the surfaces to different monoprotein solutions. Each protein showed a different process of adsorption and properties of the adlayer-calculated using the Voigt model. The competition experiments showed that BSA displaced larger proteins such as Fn and Fbg when BSA was introduced as the second protein in the system, whereas the larger proteins laid on top of BSA forming an adsorbed protein bi-layer when those were introduced secondly in the system.

Keywords: QCM, Human plasma fibronectin, Induced conformational-changes, Von-willebrand-factor, BSA, Protein adsortion, Polymer surfaces, Solid-surfaces, Viscoelastic properties, Globular-proteins


Rico, P., Rodriguez Hernandez, J. C., Moratal, D., Altankov, G., Monleon Pradas, M., Salmeron-Sanchez, M., (2009). Substrate-induced assembly of fibronectin into networks. Influence of surface chemistry and effect on osteoblast adhesion Tissue Engineering Part A , 15, (00), 1-11

The influence of surface chemistry -substrates with controlled surface density of -OH groups- on fibronectin conformation and distribution is directly observed by Atomic Force Microscopy (AFM). FN fibrillogenesis, which is known to be a process triggered by interaction with integrins, is shown in our case to be induced by the substrate (in absence of cells), which is able to enhance FN-FN interactions leading to the formation of a protein network on the material surface. This phenomenon depends both on surface chemistry and protein concentration. The level of the FN fibrillogenesis was quantified by calculating the fractal dimension of the adsorbed protein from image analysis of the AFM results. The total amount of adsorbed FN is obtained by making use of a methodology which employs western-blotting combined with image analysis of the corresponding protein bands, with the lowest sensitivity threshold equal to 15 ng of adsorbed protein. Furthermore, FN adsorption is correlated to human osteoblast adhesion through morphology and actin cytoskeleton formation. Actin polymerization is in need of the formation of the protein network on the substrate's surface. Cell morphology is more rounded (as quantified by calculating the circularity of the cells by image analysis) the lower the degree of FN fibrillogenesis on the substrate.

Keywords: Cell-adhesion, Conformational-changes, Electron-microscopy, Protein adsorption, Fractal dimension, Integrin binding, Biocompatibility, Monolayers, Matrix, Fibrillogenesis