Academic literature on the topic 'Micro-patterned surface'

Pressure sensitive adhesive surfaces are often inspired by nature. Miming the toe-surface of gecko, engineered surfaces made of thousands of micro-pillars show promising adhesive properties. This surfaces, covered with cylindrical pillars arranged into a pattern have adhesive properties greatly dependent on the geometrical characteristics. In this thesis, have been studied successively two models of micro-patterned surfaces, one two-dimensional, the other in three-dimensional using a FEM tool. Varying geometry parameters, has been determined optimal geometries to improve adhesive strength on these biomimetic, micropatterned surfaces. This study concludes to the non-adaptability of one-level scale micropatterned surface to large area of adhesion, to the strong advantage from the point of adhesion per contact area for high aspect ratio at each level of the geometry and study the opportunity of hierarchical structures. Some further suggestions of improvements to adhesion properties are discussed in the final chapter.

Interfacial features of polymers are a complex, fascinating topic, and industrially very important. There is clearly a need to understand interactions between polymer layers as they can be used for controlling surface properties, colloidal stability and lubrication. The aim of my Ph.D study was to investigate fundamental phenomena of polymers at interfaces, covering adsorption, interactions between polymer layers and surfactants, surface forces and friction between adsorbed layers. A branched brush layer with high water content was formed on silica surfaces by a diblock copolymer, (METAC)m-b-(PEO45MEMA)n, via physisorption. The adsorption properties were determined using several complementary methods. Interactions between pre-adsorbed branched brush layers and the anionic surfactant SDS were investigated as well. Surface forces and friction between polymer layers in aqueous media were investigated by employing the Atomic Force Microscopy (AFM) colloidal probe technique. Friction forces between the surfaces coated by (METAC)m-b-(PEO45MEMA)n in water are characterized by a low friction coefficient. Further, the layers remain intact under high load and shear, and no destruction of the layer was noted even under the highest pressure employed, about 50 MPa. Interactions between polymer layers formed by a temperature responsive diblock copolymer, PIPOZ60-b-PAMPTMA17 (phase transition temperature of 46.1 °C), was investigated in the temperature interval 25-50 °C by using the AFM colloidal probe technique. Friction between the layers increases with increasing temperature (25-45 °C), while at 50 °C friction was found to be slightly lower than that at 45 °C. We suggest that this is due to decreased energy dissipation caused by PIPOZ chains crystallizing in water above the phase transition temperature. The structure of 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) bilayers was determined by X-ray reflectometry. Surface forces and friction between DPPC bilayer-coated silica surfaces were measured utilizing the AFM colloidal probe technique. Our study showed that DPPC bilayers are able to provide low friction forces both in the gel (below ≈ 41°C) and in the liquid crystalline state (above ≈ 41°C). However, the load bearing capacity is lower in the gel state. This is attributed to a higher rigidity and lower self-healing capacity of the DPPC bilayer in the gel state. Friction forces in single asperity contact acting between a micro-patterned silicon surface and an AFM tip was measured in air. We found that both nanoscale surface heterogeneities and the µm-sized depressions affect friction forces, and considerable reproducible variations were found along a particular scan line. Nevertheless, Amontons’ first rule described average friction forces reasonably well. Amontons’ third rule and Euler’s rule were found to be less applicable to our system.<br><p>QC 20141209</p>

S’han dipositat capes primes d’hidrogel per tal de modificar les propietats superficials i millorar el comportament dels biomaterials. Dues de les tècniques de deposició química en fase vapor més comunes s’han estudiat per poder dur a terme aquestes modificacions. La deposició química foto-iniciada en fase vapor (piCVD) és un mètode simple, ràpid i no agressiu que permet depositari films d’hidrogel. És un mètode que s’inicia a la superfície de la mostra i que permet recobrir de manera homogènia superfícies tridimensionals com és el cas de les micro-partícules. El piCVD ofereix un ventall molt ampli d’hidrogels amb capacitat d’absorbir aigua, incorporant co-monòmers amb diferents propietats. Els hidrogels poden ser dissenyats perquè la reactivitat es localitzi a nivell superficial, millorant d’aquesta manera la funcionalització química dels hidrogels. Tanmateix, un nou mètode s’ha utilitzat per micro-estructurar les superfícies durant la deposició via piCVD per obtenir hidrogels amb comportaments especials. Els hidrogels termo-sensibles s’han obtingut via deposició química iniciada en fase vapor (iCVD). S’ha desenvolupat una llibreria d’hidrogels termo-sensibles, els quals exhibeixen una temperatura de transició molt marcada. La microbalança de quars amb dissipació (QCM-D) s’ha fet servir per analitzar la transició d’aquests films. La combinació de les propietats que ofereixen els films termo-sensibles dona la possibilitat de dissenyar una plataforma per prevenir la formació de biofilms.<br>Se han depositado capas delgadas de hidrogel para lamodificación superficial y mejora del comportamiento de los biomateriales. Dos de las técnicasmás comunes de deposición química en fase vapor se han estudiado para llevar a cabo estas modificaciones. La deposición química foto-iniciada en fase vapor (piCVD) es un método simple, rápido y no agresivo que permite depositar films de hidrogel. Es un método que se inicia en la superficie de la muestra y que permite recubrir de manera homogénea superficies tridimensionales como es el caso de las micro-partículas. El piCVD ofrece un abanico muy amplio de hidrogeles con capacidad de absorber agua, incorporando co-monomeros con diferentes propiedades. Los hidrogeles se pueden diseñar para que la reactividad se localice a nivel superficial, mejorando de esta manera la funcionalización química de los hidrogeles. Así mismo, un nuevo método se ha utilizado para micro-estructurar las superficies durante la deposición vía piCVD para obtener hidrogeles con comportamientos especiales. Los hidrogeles termo-sensibles se han obtenido vía deposición química iniciada en fase vapor (iCVD). Se ha desarrollado una librería de hidrogeles termo-sensibles, los cuales exhiben una temperatura de transición muy marcada. La microbalanza de cuarzo con disipación (QCM-D) se ha utilizado para analizar la transición de este film. La combinación de las propiedades que ofrecen los films termo-sensibles da la posibilidad de diseñar una plataforma para prevenir la formación de biofilms.<br>Thin hydrogel films have been deposited to modify surface properties and improve biomaterials performance. Two of the most common chemical vapor deposition techniques have been studied to carry out these modifications. Photo-initiated chemical vapor deposition piCVD has been developed as a simple, not aggressive and easy method for the deposition of thin hydrogel films. This method follows a versatile surface-driven reaction process that allows homogeneous coating of both 2D and 3D geometries, such as microspheres. piCVD offers the possibility to fabricate a wide range of swellable thin films, incorporating co-monomers with different properties, such as amine-reactivity, suitable for further modification. The hydrogels can be designed by nano-confining the reactivity to the near surface region, improving the chemical functionality of hydrogels. In addition, a new method to create micro-patterned surfaces can be applied during piCVD deposition to design surfaces having special behavior. Thermo-responsive thin hydrogel films have also been obtained via initiated chemical vapor deposition (iCVD). A library of thermo-sensitive films exhibiting controlled lower critical solution temperatures (LCST) has been generated. Quartz crystal microbalance with dissipation analysis has been used to analyze the phase-transition of these films. The intrinsic properties of thermo-sensitive hydrogels, such as tunable surface hydrophilicity or release of film-entrapped molecules, open the possibility to design systems for controlling biofilm formation.

ABSTRACT INTERACTION BETWEEN MICRO AND NANO PATTERNED POLYMERIC SURFACES AND DIFFERENT CELL TYPES &Ouml<br>z&ccedil<br>elik, Hayriye Ph.D., Department of Biology Supervisor: Prof. Dr. Vasif Hasirci Co-Supervisor: Dr. Celestino Padeste August 2012, 139 pages Micro and nanopatterned surfaces are powerful experimental platforms for investigating the mechanisms of cell adhesion, cell orientation, differentiation and they enable significant contributions to the fields of basic cell and stem cell biology, and tissue engineering. In this study, interaction between micro and nanopatterned polymeric surfaces and different cell types was investigated. Three types of micropillars were produced by photolithography (Type 1-3), while nanometer sized pillars were produced in the form of an array by electron beam lithography (EBL). Replica of silicon masters were made of polydimethylsiloxane (PDMS). Polymeric [P(L-D,L)LA and a P(L-D,L)LA:PLGA blend] replica were prepared by solvent casting of these on the PDMS template and used in in vitro studies. The final substrates were characterized by various microscopic methods such as light microscopy, atomic force microscopy (AFM) and scanning electron microscopy (SEM). In order to investigate deformation of the nucleus in response to the physical restrictions imposed by micropillars, Type 1 and Type 2 pillars were used. These substrates were covered with pillars with different interpillar distances. While Type 1 is covered with symmetrically (in X-Y directions) distributed pillars, Type 2 pillars were distributed asymmetrically and the inter-pillar distances were increased. Nuclei deformation of five cell v types, two cancer cell lines (MCF7 and Saos-2), one healthy bone cell (hFOB1.19), one stem cell (bone marrow origined mesemchymal stem cells, BMSCs) and one standard biomaterial test cell type, (L929) fibroblasts was examined by using fluorescence microscopy and SEM. The nuclei of Saos-2 and MCF7 cells were found to be deformed most drastically. Nucleus deformation and intactness of nuclear membrane was examined by Anti- Lamin A staining. The interaction of the cells with micropillars was visualized by labelling focal adhesion complexes (FAC). Wettabilities of patterned and smooth surfaces were determined. As the patterns become denser (closer micropillars, Type 1) the hydrophobicity increased. Similar to water droplets, the cells were mostly spread at the top of the Type 1 pillars. The number of cells spread on the substrate surface was much higher on Type 2 patterned films. In order to support these qualitative findings, nucleus deformation was quantified by image analysis. Frequency of nucleus deformation was determined as the ratio of deformed to the total number of nuclei (%). In order to quantify the intensity of nuclei deformation, their circularity was evaluated. In addition to nucleus deformation, alterations in the ratio of cell area-to-nucleus area in response to micropillars were determined by image analysis. The results indicated that cancerous cells were more deformable. The qualitative microscopic evaluation and the data obtained by quantification of the nucleus and cellular deformation were in good agreement. In addition, the findings were consistent with expectations which suggest that cancerous cells are &ldquo<br>softer&rdquo<br>. In the second part of the research the force applied by the cells on arrays of micropillars with high aspect ratios (Type 3 substrates) during tugging at the pillars was investigated. Micropillars were produced using P(L-D,L)LA as well as a 60:40 blend of P(L-D,L)LA with PLGA. The blend is a material with lower stiffness than P(L-D,L)LA. The mechanical properties of the two materials were determined by tensile testing of solvent cast films. Deformation of Type 3 micropillars by the cellular tugging force of Saos-2 and L929 was studied by fluorescence and SEM microscopy, both on stiff and softer substrates. Displacements of the centers nodes of the pillars were evaluated from SEM micrographs. On the stiff surface, the two cell types bent the pillars to the same extent. On the other softer substrate (blends), however, the maximum displacements observed with Saos-2 cells were higher than the ones caused on the stiffer substrate or the ones caused by L929 cells. It is reported that stiffness of the substrate can determine stem cell lineage commitment. In order to examine the effects of change of substrate stiffness on osteogenic differentiation of BMSCs, osteopontin (OPN) expression was determined microscopically. It was found that osteogenic differentiation is enhanced when BMSCs are cultured on P(L-D,L)LA Type 3 pillars. vi In the last part of research, arrays of nanopillars whose interpillar distances systematically varied to form different fields were examined in terms of adhesion and alignment in order to determine the differential adhesion of BMSCs and Saos-2 cells. The difference in their adhesion preference on nanopillar arrays was quantified by image analysis. It was observed that BMSCs and Saos-2 cells behaved in an opposite manner with respect to each other on the fields with the highest density of nanopillars. The BMSCs avoided the most densely nanopillar covered fields and occupied the pattern free regions. The Saos-2, on the other hand, occupied the most densely nanopillar covered fields and left the pattern free regions almost unpopulated. It was also found that both BMSCs and Saos-2 cells aligned in the direction of the shorter distance between the pillars. Both BMSCs and Saos-2 cells started to align on the pillars if the distance in any direction was &gt<br>1.5 &mu<br>m. To better understand the effects of chemical and physical cues, protein coating and material stiffness were tested as two additional parameters. After fibronectin coating, the surfaces of P(L-D,L)LA films with the highly dense pillar covered fields, which were avoided when uncoated, were highly populated by the BMSC. Similarly, decreasing the stiffness of a surface which was normally avoided by the BMSCs made it more acceptable for the cells to attach.

The interaction between droplets and solid surfaces is of great importance in industrial applications, biochemical processes, and fundamental materials research on surface wettability. In this work, a three-dimensional spectral boundary element method has been employed to investigate the dynamics of a viscous droplet moving under gravity influence normal and parallel to a micro-patterned solid surface. The dynamics of the droplet moving perpendicular to the substrate are investigated under the influence of Bond number, droplet size, and topological features of the substrate. We find that the droplet dynamics can be controlled by varying Bond number, droplet size, and pattern height and width; however, the pattern length has little effect. For a droplet moving parallel to the surface, the Bond number and pattern projection direction greatly change the droplet dynamics. However, after moving past the pattern, the droplet position, velocity, and deformation return to that of a flat-plate solution.

Experiments were performed to characterize hydraulic jumps that form due to liquid jet impingement on superhydrophobic surfaces with alternating micro-ribs and cavities. If the surface is unimmersed, a surface tension based transition into droplets occurs, so a known depth of water was imposed downstream from the hydraulic jump to ensure the existence of a hydraulic jump. The surfaces are characterized by the cavity fraction, which is defined as the width of a cavity divided by the combined width of a cavity and an adjoining rib. Four different surface designs were studied, with respective cavity fractions of 0 (smooth surface), 0.5, 0.8, and 0.93. Each surface was tested in its naturally hydrophilic state where water was allowed to flood the cavities, as well as with a hydrophobic coating which prevented water from entering the cavities and created a liquid-gas interface over much of the surface. The experimental data spans a Weber number range (based on the jet velocity and radius) of 3x102 to 1.05x103 and a corresponding Reynolds number range of 1.15x104 to 2.14x104. While smooth surfaces always result in circular transitions, for any rib and cavity patterned surface the flow exhibits a nearly elliptical transition from the thin film, where the major axis of the ellipse is parallel to the ribs, concomitant with greater slip in that direction. When the downstream depth is small and a superhydrophobic surface is used, the water is completely expelled from the surface, and the thin film breaks up into droplets due to surface tension interactions. When the downstream depth is large or the surface is hydrophilic a hydraulic jump exists. When the water depth downstream of the jump increases, the major and minor axis of the jump decreases due to an increase in hydrostatic force, following classical hydraulic jump behavior. The experimental results indicate that for a given cavity fraction and downstream depth, the radius of the jump increases with increasing Reynolds number. The jump radius perpendicular to the ribs is notably less than that for a smooth surface, and this radius decreases with increasing cavity fraction. When comparing flow over superhydrophobic (coated) surfaces to patterned, hydrophilic (uncoated) surfaces, a general increase is seen in the radial location of the hydraulic jump in the direction of the ribs, while no statistically significant change is seen in the direction perpendicular to the ribs.

The aim of this thesis was to develop novel micro and nano polymer substrates through different surface patterning techniques to compare their effect on human lung fibroblast (LL24) and bovine aorta endothelium (BAE-1) cell behaviours. The cells ability to adhere, proliferate and migrate were studied through the use of MTT assays and live cell tracking. Laser processing in a directional manner resulted in polyurethane surfaces having a ploughed field effect with micron-scale features a novel surface. In contrast, abrasive polishing in a directional and random manner resulted in polyurethane surfaces having sub-micron scale features orientated in a linear or random manner. The cell results showed that for both the LL24 and BAE-1 cells the laser and randomly organised abrasive surface prompted cell adhesion when compared to the linear polished surface and non-patterned surfaces. The linear polished features did not enhance cell proliferation for wither cell type when compared to the flat surface. For cell migration a clear difference can be seen between the cell types with the LL24 cells showing a decrease in cell migration on the laser and random abrasive surface. The BAE-1 cells showed enhanced migration on the non-patterned surface when compared to the other surfaces. This work was expanded to include different polished surfaces through the use of different grades of polishing paper. The results for the LL24 cells showed that though the polished surfaces promoted adhesion when compared to the non-patterned surface there was no clear difference between the surfaces for cell proliferation and migration. The BAE-1 cells results showed a similarity to the LL24 cells with the polished surfaces promoting adhesion when compared to the non-patterned surface. There was a clear distinction for the proliferation results with the LL24 cells showing enhanced proliferation on the scratched surface, this is in contrast to the BAE-1 cells which were enhanced on the non-patterned surfaces compared to the scratched surfaces. A final study was performed to introduce the use of machine grinding to generate surfaces with micro-sized features and their ability to affect cell behaviour. Results are presented which show that polyurethane castings of the ground surfaces can promote LL24 cell adhesion and migration, demonstrating that this method can be a cost effective technique to be used in this field.