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by Keyword: XPS


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Veeregowda, D. H., van der Mei, H. C., de Vries, J., Rutland, M. W., Valle-Delgado, J. J., Sharma, P. K., Busscher, H. J., (2012). Boundary lubrication by brushed salivary conditioning films and their degree of glycosylation Clinical Oral Investigations , 16, (5), 1499-1506

Objectives: Toothbrushing, though aimed at biofilm removal, also affects the lubricative function of adsorbed salivary conditioning films (SCFs). Different modes of brushing (manual, powered, rotary-oscillatory or sonically driven) influence the SCF in different ways. Our objectives were to compare boundary lubrication of SCFs after different modes of brushing and to explain their lubrication on the basis of their roughness, dehydrated layer thickness, and degree of glycosylation. A pilot study was performed to relate in vitro lubrication with mouthfeel in human volunteers. Materials and methods: Coefficient of friction (COF) on 16-h-old SCFs after manual, rotary-oscillatory, and sonically driven brushing was measured using colloidal probe atomic force microscopy (AFM). AFM was also used to assess the roughness of SCFs prior to and after brushing. Dehydrated layer thicknesses and glycosylation of the SCFs were determined using X-ray photoelectron spectroscopy. Mouthfeel after manual and both modes of powered brushing were evaluated employing a split-mouth design. Results: Compared with unbrushed and manually or sonically driven brushed SCFs, powered rotary-oscillatory brushing leads to deglycosylation of the SCF, loss of thickness, and a rougher film. Concurrently, the COF of a powered rotary-oscillatory brushed SCF increased. Volunteers reported a slightly preferred mouthfeel after sonic brushing as compared to powered rotating-oscillating brushing. Conclusion: Deglycosylation and roughness increase the COF on SCFs. Clinical relevance: Powered rotary-oscillatory brushing can deglycosylate a SCF, leading to a rougher film surface as compared with manual and sonic brushing, decreasing the lubricative function of the SCF. This is consistent with clinical mouthfeel evaluation after different modes of brushing.

Keywords: AFM, Friction, Glycosylation, Salivary conditioning film, Toothbrushing, XPS


Michiardi, A., Helary, G., Nguyen, P. C. T., Gamble, L. J., Anagnostou, F., Castner, D. G., Migonney, V., (2010). Bioactive polymer grafting onto titanium alloy surfaces Acta Biomaterialia 6, (2), 667-675

Bioactive polymers bearing sulfonate (styrene sodium sulfonate, NaSS) and carboxylate (methylacrylic acid, MA) groups were grafted onto Ti6Al4V alloy surfaces by a two-step procedure. The Ti alloy surfaces were first chemically oxidized in a piranha solution and then directly subjected to radical polymerization at 70 °C in the absence of oxygen. The grafted surfaces were characterized by X-ray photoelectron spectroscopy (XPS), time-of-flight secondary ion mass spectrometry (ToF-SIMS) and the toluidine blue colorimetric method. Toluidine blue results showed 1-5 μg cm-2 of polymer was grafted onto the oxidized Ti surfaces. Grafting resulted in a decrease in the XPS Ti and O signals from the underlying Ti substrate and a corresponding increase in the XPS C and S signals from the polymer layer. The ToF-SIMS intensities of the S- and SO- ions correlated linearly with the XPS atomic percent S concentrations and the ToF-SIMS intensity of the TiO3H2- ion correlated linearly with the XPS atomic per cent Ti concentration. Thus, the ToF-SIMS S-, SO- and TiO3H2- intensities can be used to quantify the composition and amount of grafted polymer. ToF-SIMS also detected ions that were more characteristic of the polymer molecular structure (C6H4SO3- and C8H7SO3- from NaSS, C4H5O2- from MA), but the intensity of these peaks depended on the polymer thickness and composition. An in vitro cell culture test was carried out with human osteoblast-like cells to assess the influence of the grafted polymers on cell response. Cell adhesion after 30 min of incubation showed significant differences between the grafted and ungrafted surfaces. The NaSS grafted surfaces showed the highest degree of cell adhesion while the MA-NaSS grafted surfaces showed the lowest degree of cell adhesion. After 4 weeks in vivo in rabbit femoral bones, bone was observed to be in direct contact with all implants. The percentage of mineralized tissue around the implants was similar for NaSS grafted and non-grafted implants (59% and 57%). The MA-NaSS grafted implant exhibited a lower amount of mineralized tissue (47%).

Keywords: Bioactive polymers, Osteointegration, Titanium alloy, ToF-SIMS, XPS


Zazoua, A., Kherrat, R., Caballero, D., Errachid, A., Jaffrezic-Renault, N., Bessueille, F., Leonard, D., (2009). Characterisation of a Cr(VI) sensitive polysiloxane membrane by x-ray photoelectron spectrometry and atomic force microscopy Sensor Letters 6th Maghreb-Europe Meeting on Materials and Their Applications for Devices and Physical, Chemical and Biological Sensors , AMER SCIENTIFIC PUBLISHERS (Rabat, Morocco) 7, (5), 995-1000

Cr(VI) sensitive polysiloxane membranes containing tributylphosphate (TBP) or trioctylphosphine oxide (TOPO) were characterized in this study. TBP and TOPO as carriers, have a high selectivity for Cr(VI). The Potentiometric response of EMIS (Electrolyte/Membrane/Insulator/Semiconductor) sensors presents a quasi-nernstian response for Cr2O2-7 exchange. The ion exchange is shown by X-ray photoelectron spectrometry (XPS), the binding energy of the Cr 2p1/2 peak corresponding to Cr(VI) and the atomic composition after exposure to Cr(VI) shows a factor 1.7 higher for silopreneTBP membrane. The conformational topography of both polymeric membranes was characterized by Atomic Force Microscopy (AFM), the exchange of Cr(VI) leading to a heterogeneous topographic state. Adhesion force measurements are also performed to study the properties of adhesion of both selective membranes with a non-functionalized Si AFM tip and with an OTS functionalized one to study the interactions between the tip and the membrane, in liquid before and after the exposure of the membrane to ion chromium. The presence of the ionophores does not practically change the adhesion force compared to pure polysiloxane, showing a good solubility of the ionophore and the orientation of the alkyl chains towards the polysiloxane surface. After the exchange with Cr(VI), the adhesion force decreases drastically due to the hydrophilic character of the surface, complex of Cr(VI) with the P-O groups of both ionophore being oriented towards the surface.

Keywords: AFM, Electrolyte/membrane/insulator/semiconductor structures, Polysiloxane membrane, Xps


Barhoumi, H., Haddad, R., Maaref, A., Bausells, J., Bessueille, F., Leonard, D., Jaffrezic-Renault, N., Martelet, C., Zine, N., Errachid, A., (2008). Na+-implanted membrane for a capacitive sodium electrolyte-Insulator-Semiconductor microsensors Sensor Letters International Conference of Thermal, Mechanical and Multiphysics Simulation and Experiments in Microelectronics and Microsystems (ed. -----), Amer Scientific Publishers (Lombardy, Italy) 6, (1), 204-208

Ion implanted Insulator-Semiconductor (IS) sensor that specifically detects Na+ ions have been developed using ion implantation technique. Na+ ions were directly implanted with ion energies 30, 45, and 60 keV into the IS (oxidized Si3N4/Si3N4/SiO2/P-Si) structures previously covered with a thin aluminum layer. X-ray photoelectron spectroscopy (XPS) characterization shows that sodium and aluminum ions were implanted into the oxidized Si3N4 insulating layer surface. Their atomic percentage depending on energy, fluence of the implanted ion and of the annealing temperature. The sen sitivity of the ion-implanted IS structure for Na+ and of some interfering (K+, Li+, H+, and NH4+) ions was investigated using high frequency capacitance-voltage measurements. Under optimal i mplantation conditions such as energy, fluence and annealing temperature, the developed sodium microsensor demonstrates quasi-nernstian sensitivity (50 +/- 2 mV/pNa) in the concentration range from 10(-3.7) to 10(-1) M and high lifetime greater than 16 months without any loss of sensitivity.

Keywords: Na+ microsensor, Ion implantation, XPS, C-V measurements