We studied the adsorption of bovine serum albumin (BSA) from phosphate-buffered saline (pH 7.4) to hydrophilic and hydrophobic surfaces. Attenuated total reflection Fourier transform infrared spectroscopy, supported by spectral simulation, allowed us to determine with high precision the amount of BSA adsorbed (surface coverage) and its structural composition. The adsorbed BSA molecules had an alpha-helical structure on both hydrophobic and hydrophilic surfaces but had different molecular conformations and adsorption strengths on the two types of surface. Adsorption of BSA was saturated at around 50% surface coverage on the hydrophobic surface, whereas on the hydrophilic surface the adsorption reached 95%. The BSA molecules adsorbed to the hydrophilic surface with a higher interaction strength than to the hydrophobic surface. Very little adsorbed BSA could be desorbed from the hydrophilic surface, even using 0.1 M sodium dodecyl sulfate, a strong detergent solution. The formation of BSA-phosphate surface complexes was observed under different BSA adsorption conditions on hydrophobic and hydrophilic surfaces. The formation of these complexes correlated with the more efficient blocking of nonspecific interactions by the adsorbed BSA layer. Results from the molecular modeling of BSA interactions with hydrophobic and hydrophilic surfaces support the spectroscopic findings.
Hybrid organic-inorganic films consisted of molecular layers of a Keggin-structure polyoxometalate (POM: 12-tungstophosphoric acid, H(3)PW(12)O(40)) and 1,12-diaminododecane (DD) on 3-aminopropyl triethoxysilane (APTES)-modified silicon surface, fabricated via the layer-by-layer (LBL) self-assembly method are evaluated as molecular materials for electronic devices. The effect of the fabrication process parameters, including primarily compositions of deposition solutions, on the structural characteristics of the POM-based multilayers was studied extensively with a combination of spectroscopic methods (UV, FTIR, and XPS). Well-characterized POM-based films (both single-layers and multilayers) in a controlled and reproducible way were obtained. The conduction mechanisms in single-layered and multilayered structures were elucidated by the electrical characterization of the produced films supported by the appropriate theoretical analysis. Fowler-Nordheim (FN) tunneling and percolation mechanisms were encountered in good correlation with the structural characteristics of the films encouraging further investigation on the use of these materials in electronic and, in particular, in memory devices.
The composition, structure, and thickness of the oleate self-assembled layers on apatite have been determined by a method based on experimental infrared reflection data. This work demonstrates the versatility of the proposed method. The advantages and limitations of this method are examined and explored in detail. From the analysis of the reflection spectra of the same sample recorded at specific angles of incidence and different polarizations, the orientations of the carboxylate group and hydrocarbon chain with respect to the surface normal were calculated. The use of the absorbance components instead of the electric field components is proposed in this evaluation. The studies were performed on three samples characteristic for different stages of adsorption layer formation. At close to monolayer coverage, the major part of the adsorbed molecules is well-organized, and two different structural domains are observed. The average orientation angles between the transition moment of the asymmetric stretching vibration of the two types of carboxylate groups and the surface normal are 83" and 62". These two well-distinguish orientations of the carboxylate group are proposed to be associated with two different types of calcium sites present at the (100) plane of apatite. At a coverage close to two statistical monolayers, the molecules adsorbed on the top of the first well-ordered layer are randomly spread and oriented almost parallel to the interface. There is a very low intermolecular interaction between them, which is contrary to a strong lateral interaction in the first close-packed layer. Apatite with multilayer coverage (about 10 statistical monolayers), produced by the surface precipitation mechanism, shows a well-organized structure, with two different orientations of the carboxylate groups, which are very similar to those observed at close to monolayer coverage. The observed water molecules in the adsorption layers play an important role in the formation of organized surface structures.
Two fluorinated/siloxane copolymers, O5/19 and D5/3, carrying 6 and 8 CF(2) groups in the fluoroalkyl tail, respectively, were used as the surface-active components of cured poly(dimethylsiloxane) (PDMS) blends at different loadings (0.3-5.0 wt % with respect to PDMS). The surface chemical composition was determined by angle-resolved X-ray photoelectron spectroscopy at the takeoff angles theta of 0 degrees, 60 degrees, and 75 degrees. It was found that the fluorinated copolymer was surface-segregated, and in-depth segregation (approximately 5 nm) depended upon the chemical structure of the copolymer. The surface fluorine atomic percentage of the blends with D5/3 was up to 3 orders of magnitude higher than the theoretical value expected for ideal homogeneous samples. Moreover, small amounts of the copolymer in the blends were sufficient to saturate the outermost surface in fluorine content. The chemical composition of the surface-segregated nanostructure of the films was also proven to be affected by external environment, namely, exposure to water.
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