Global ETD Search

591	Phospholipid membranes in biosensor applications : Stability, activity and kinetics of reconstituted proteins and glycolipids in supported membranes Gustafson, Inga January 2004 (has links) <p>In this study the formation of supported membranes onto planar solid supports has been investigated. The stability and activity of reconstituted membrane receptors has been studied. The potential use of such preparations in biosensor applications is discussed.</p><p>The lipid films were made by the Langmuir Blodgett and by the liposome fusion techniques. These supported films were characterised by ellipsometry, atomic force microscopy, surface plasmon resonance (SPR) and resonant mirror techniques. The thickness of the films was in agreement with that of a cell membrane. The kinetics of formation of the lipid films was studied and discussed.</p><p>The proteins, bacteriorhodopsin, cytochrome oxidase, acetylcholinesterase and the nicotinic acetylcholine receptor were reconstituted into the supported membrane. The subsequent analysis showed that the proteins were individually distributed and that the activity was retained, in some cases for several weeks after immobilisation.</p><p>The glycolipids, GM1, GM2, GD1b, asialo-GM1, globotriaosylceramide, lactosylceramide and galactosylceramide, were also reconstituted into the supported membranes. Their specific interaction with the toxin ricin or with its B-chain was examined using SPR. The affinity of intact toxin and of its B-chain differed markedly and was pH dependent. The carbohydrate chain length and charge density of the glycolipids also influenced the affinity.</p> Biochemistry Phospholipid films Liposomes Membrane proteins Glycolipids Ellipsometry Langmuir Blodgett (LB) Surface plasmon resonance (SPR) Resonant mirror (RM) Atomic force microscopy (AFM) Biosensors Biokemi Biochemistry Biokemi
592	Antibody-conjugated Gold Nanoparticles integrated in a fluorescence based Biochip Ljungblad, Jonas January 2009 (has links) <p>Gold nanoparticles exhibit remarkable optical properties and could prove useful in sensitive biosensing applications. Upon illumination gold nanoparticles produce localized surface plasmons, which influence nearby fluorophores and an enhancement in their fluorescence intensity can be observed. This property makes gold nanoparticles attractive for enhancing optical signals.</p><p>In this project gold nanoparticles were functionalized with an antibody and immobilized to the surface of an existing biochip platform based on fluorescence. The aim was to investigate the possibility of obtaining an increased fluorescence signal from the gold nanoparticles. Two different conjugation procedures were investigated, direct physisorption and covalent attachment of the antibodies to the particles. Activity of bound antibodies was confirmed in both cases.</p><p>The on-chip fluorescence intensity produced by the different conjugates was monitored by use a specialized fluorescence reader designed for point-of-care use. AFM and SEM were used to determine the surface concentration of particles. A correlation between the produced fluorescence intensity and the surface concentration could be seen.</p> Gold nanoparticles Bioconjugation Metal enhanced fluorescence Localized Surface Plasmon Resonance Ultra Violet/Visible spectroscopy Atomic Force Microscopy Transmission Electron Microscope Scanning Electron Microscope Molecular physics Molekylfysik
593	Spatially Controlled Covalent Immobilization of Biomolecules on Silicon Surfaces Pavlovic, Elisabeth January 2003 (has links) <p>The work described in this thesis aims to achieving surface patterning through chemical activation of thiolated silicon oxide surfaces, resulting in a spatially controlled covalent immobilization of biomolecules with high resolution.</p><p>Existing chemical methods to immobilize molecules on surfaces do not reach below the micrometer scale while the ones allowing for spatial control mostly lead to non-covalent adsorption of molecules on surfaces, or require several successive chemical reactions to obtain the final covalent immobilization. Methods with improved chemical processes and novel surface modification techniques had to be developed. </p><p>A basic need for studying interactions of biomolecules on chemically modified surfaces with high resolution is the ability to obtain a simple, inexpensive method resulting in ultraflat densely packed and reproducible organic monolayers. Therefore, a new method for silicon oxide chemical derivatization, fulfilling these requirements, was developed. </p><p>Thiol derivatized silicon oxide surfaces allow for a diversity of activation reactions to occur, resulting in thiol-disulfide exchange. The electrooxidation of surface-bound thiol groups was investigated as a way of generating reactive thiolsulfinates/thiolsulfonates, by application of a positive potential difference to the silicon surfaces. Peptide molecules containing thiol groups were successfully immobilized to the electroactivated surfaces. In addition, this new chemical activation method offers the possibility to release the bound molecules in order to regenerate the surfaces. Subsequently, the thiolated surfaces can be reactivated for further use.</p><p>Since the activated area depends directly on the size of the electrodes used for the oxidation, nanoscale activation of the thiolated surfaces was performed by use of an AFM tip as counter-electrode. Electrooxidized patterns, with a line width ranging from 70 nm to 200 nm, were obtained. A thiol-rich protein, b-galactosidase, was selectively immobilized onto the electroactivated patterns.</p><p>An electrochemical version of microcontact printing was developed in order to activate large surface areas with micrometer scale patterns. Conductive soft polymer stamps were produced using an evaporated aluminum coating. Patterned electroactivation of thiols was achieved, and polystyrene beads were subsequently specifically immobilized onto the patterns.</p><p>As a conclusion, these different projects resulted in a strategy enabling the achievement of nanoscale and microscale positioning and immobilization of biomolecules on silicon surfaces, with potential reversibility and reuse of the surfaces.</p> Biotechnology silicon oxide electrooxidation sulfur nanotechnology self-assembled monolayers atomic force microscopy biomolecules covalent immobilization reversibility Bioteknik Bioengineering Bioteknik
594	Simulation of the Molecular Interactions for the Microcantilever Sensors Khosathit, Padet 11 1900 (has links) Microcantilever sensor has gained much popularity because of its high sensitivity and selectivity. It consists of a micro-sized cantilever that is usually coated on one side with chemical/biological probe agents to generate strong attraction to target molecules. The interactions between the probe and target molecules induce surface stress that bends the microcantilever. This current work applied the molecular dynamics simulation to study the microcantilever system. Lennard-Jones potentials were used to model the target-target and target-probe interactions and bond bending potentials to model the solid cantilever beam. In addition, this work studied the effect of probe locations on the microcantilever deflection. The simulation results suggest that both target-target and target-probe interactions as well as the probe locations affect the arrangement of the bonds; in term of the bonding number, the area containing the bonded molecules, and the distances between them. All these factors influence the microcantilever deflection. Microcantilever Sensor Molecular Interactions Molecular Dynamics Simulation Nanocantilever Lennard-Jones Potential Biosensor Chemical Detection Lattice Spring Bond Bending Potential Atomic Force Microscopy
595	Hydrophobic surfaces: Effect of surface structure on wetting and interaction forces Hansson, Petra M January 2012 (has links) The use of hydrophobic surfaces is important for many processes both in nature and industry. Interactions between hydrophobic species play a key role in industrial applications such as water-cleaning procedures and pitch control during papermaking but they also give information on how to design surfaces like hydrophobic mineral pigments. In this thesis, the influence of surface properties on wetting and interaction forces has been studied. Surfaces with close-packed particles, pore arrays, randomly deposited nanoparticles as well as reference surfaces were prepared. The atomic force microscope (AFM) was utilized for force and friction measurements while contact angles and confocal Raman microscopy experiments were mainly used for wetting studies. The deposition of silica particles in the size range of nano- to micrometers using the Langmuir-Blodgett (LB) technique resulted in particle coated surfaces exhibiting hexagonal close-packing and close to Wenzel state wetting after hydrophobization. Force measurements displayed long-range interaction forces assigned to be a consequence of air cavitation. Smaller roughness features provided larger forces and interaction distances interpreted as being due to fewer restrictions of capillary growth. Friction measurements proved both the surface structure and chemistry to be important for the observed forces. On hydrophobic pore array surfaces, the three-phase contact line of water droplets avoided the pores which created a jagged interface. The influence of the pores was evident in the force curves, both in terms of the shape, in which the three-phase contact line movements around the pores could be detected, as well as the depth of the pores providing different access and amount of air. When water/ethanol mixtures were used, the interactions were concluded to be due to ethanol condensation. Confocal Raman microscopy experiments with water and water/ethanol mixtures on superhydrophobic surfaces gave evidence for water depletion and ethanol/air accumulation close to the surface. Force measurements using superhydrophobic surfaces showed extremely long-range interaction distances. This work has provided evidence for air cavitation between hydrophobic surfaces in aqueous solution. It was also shown that the range and magnitude of interaction forces could, to some extent, be predicted by looking at certain surface features like structure,roughness and the overall length scales. / <p>QC 20121011</p> hydrophobic surface superhydrophobic surface atomic force microscopy surface forces capillary forces cavitaion surface roughness friction wetting confocal Raman contact angles surface preparation Langmuir-Blodgett
596	Study of magnetic properties of nanostructures on self-assembled patterns Malwela, Thomas. January 2010 (has links) In the current study, we give a report when oxalic acid was used as an electrolyte to synthesize an AAO template with hexagonal pore array. Optimum parameters were observed as 0.4 M of oxalic acid, anodizing voltage of 45 V, temperature of approximately 8 Â°C and the period of 120 minutes. Atomic force microscope (AFM) and High resolution scanning electron microscope (HRSEM) showed that template has an average pore diameter of 103 nm. Co and MnOx (x = 1,2) nanostructures were selectively deposited in the pores of the template using a novel atomic layer deposition (ALD) technique. The diameter sizes and the array of the nanostructures and the template were corresponding. Energy dispersive xrays (EDX) and X-ray photoelectron spectroscopy (XPS) confirmed the presence of Co and MnOx (x =1,2) on the samples while x-ray diffraction (XRD) provided an indication of their orientations. Magnetic force microscopy as main characterization tool showed the existence of multi-domains on both Co and MnOx (x =1,2) nanostructures. Self-Assembly Aluminium Anodization Nanopores Electrodeposition Cyclic Voltammetry Co nanostructures MnOx (x = 1,2) nanostructures Nanomagnetism Atomic Force Microscopy Magnetic Force Microscopy Magnetic properties Magnetic domains Domain Walls.
597	Spatially Controlled Covalent Immobilization of Biomolecules on Silicon Surfaces Pavlovic, Elisabeth January 2003 (has links) The work described in this thesis aims to achieving surface patterning through chemical activation of thiolated silicon oxide surfaces, resulting in a spatially controlled covalent immobilization of biomolecules with high resolution. Existing chemical methods to immobilize molecules on surfaces do not reach below the micrometer scale while the ones allowing for spatial control mostly lead to non-covalent adsorption of molecules on surfaces, or require several successive chemical reactions to obtain the final covalent immobilization. Methods with improved chemical processes and novel surface modification techniques had to be developed. A basic need for studying interactions of biomolecules on chemically modified surfaces with high resolution is the ability to obtain a simple, inexpensive method resulting in ultraflat densely packed and reproducible organic monolayers. Therefore, a new method for silicon oxide chemical derivatization, fulfilling these requirements, was developed. Thiol derivatized silicon oxide surfaces allow for a diversity of activation reactions to occur, resulting in thiol-disulfide exchange. The electrooxidation of surface-bound thiol groups was investigated as a way of generating reactive thiolsulfinates/thiolsulfonates, by application of a positive potential difference to the silicon surfaces. Peptide molecules containing thiol groups were successfully immobilized to the electroactivated surfaces. In addition, this new chemical activation method offers the possibility to release the bound molecules in order to regenerate the surfaces. Subsequently, the thiolated surfaces can be reactivated for further use. Since the activated area depends directly on the size of the electrodes used for the oxidation, nanoscale activation of the thiolated surfaces was performed by use of an AFM tip as counter-electrode. Electrooxidized patterns, with a line width ranging from 70 nm to 200 nm, were obtained. A thiol-rich protein, b-galactosidase, was selectively immobilized onto the electroactivated patterns. An electrochemical version of microcontact printing was developed in order to activate large surface areas with micrometer scale patterns. Conductive soft polymer stamps were produced using an evaporated aluminum coating. Patterned electroactivation of thiols was achieved, and polystyrene beads were subsequently specifically immobilized onto the patterns. As a conclusion, these different projects resulted in a strategy enabling the achievement of nanoscale and microscale positioning and immobilization of biomolecules on silicon surfaces, with potential reversibility and reuse of the surfaces. Biotechnology silicon oxide electrooxidation sulfur nanotechnology self-assembled monolayers atomic force microscopy biomolecules covalent immobilization reversibility Bioteknik Bioengineering Bioteknik
598	Phospholipid membranes in biosensor applications : Stability, activity and kinetics of reconstituted proteins and glycolipids in supported membranes Gustafson, Inga January 2004 (has links) In this study the formation of supported membranes onto planar solid supports has been investigated. The stability and activity of reconstituted membrane receptors has been studied. The potential use of such preparations in biosensor applications is discussed. The lipid films were made by the Langmuir Blodgett and by the liposome fusion techniques. These supported films were characterised by ellipsometry, atomic force microscopy, surface plasmon resonance (SPR) and resonant mirror techniques. The thickness of the films was in agreement with that of a cell membrane. The kinetics of formation of the lipid films was studied and discussed. The proteins, bacteriorhodopsin, cytochrome oxidase, acetylcholinesterase and the nicotinic acetylcholine receptor were reconstituted into the supported membrane. The subsequent analysis showed that the proteins were individually distributed and that the activity was retained, in some cases for several weeks after immobilisation. The glycolipids, GM1, GM2, GD1b, asialo-GM1, globotriaosylceramide, lactosylceramide and galactosylceramide, were also reconstituted into the supported membranes. Their specific interaction with the toxin ricin or with its B-chain was examined using SPR. The affinity of intact toxin and of its B-chain differed markedly and was pH dependent. The carbohydrate chain length and charge density of the glycolipids also influenced the affinity. Biochemistry Phospholipid films Liposomes Membrane proteins Glycolipids Ellipsometry Langmuir Blodgett (LB) Surface plasmon resonance (SPR) Resonant mirror (RM) Atomic force microscopy (AFM) Biosensors Biokemi Biochemistry Biokemi
599	Tuning Properties of Surfaces and Nanoscopic Objects using Dendronization and Controlled Polymerizations Östmark, Emma January 2007 (has links) In this study, dendronization and grafting via controlled polymerization techniques, atom transfer radical polymerization (ATRP) and ring-opening polymerization (ROP), have been explored. Modification of surfaces and cellulose using these techniques, which enable grafting of well-defined polymer architectures, has been investigated. The interest in using cellulose stems from its renewability, biocompatibility, high molecular weight, and versatile functionalization possibilities. Dendronization was performed using disulfide-cored didendrons of 2,2-bis(methylol)propionic acid (bis-MPA) on gold surfaces, for the formation of self-assembled monolayers. It was found that the height of the monolayer increased with increasing dendron generation and that the end-group functionality controlled the wettability of the modified surface. Superhydrophobic cellulose surfaces could be obtained when a ‘graft-on-graft’ architecture was obtained using ATRP from filter paper after subsequent post-functionalized using a perfluorinated compound. The low wettability could be explained by a combination of a high surface roughness and the chemical composition. Biobased dendronized polymers were synthesized through the ‘attach to’ route employing dendronization of soluble cellulose, in the form of hydroxypropyl cellulose (HPC). The dendronized polymers were studied as nanosized objects using atomic force microscopy (AFM) and it was found that the dendron end-group functionality had a large effect on the molecular conformation on surfaces of spun cast molecules. ATRP of vinyl monomers was conducted from an initiator-functionalized HPC and an initiator-functionalized first generation dendron, which was attached to HPC. The produced comb polymers showed high molecular weight and their sizes could be estimated via AFM of spun cast molecules on mica and from dynamic light scattering in solution, to around 100-200 nm. The comb polymers formed isoporous membranes, exhibiting pores of a few micrometers, when drop cast from a volatile solvent in a humid environment. HPC was also used to initiate ROP of ε-caprolactone, which was chain extended using ATRP to achieve amphiphilic comb block copolymers. These polymers could be suspended in water, cross-linked and were able to solubilize a hydrophobic compound. / QC 20100826 Dendrimers dendronized polymers cellulose Atom Transfer Radical Polymerization Ring-Opening Polymerization surface modification grafting superhydrophobic amphiphilic polymer block copolymer Atomic Force Microscopy Polymer chemistry Polymerkemi
600	Domain engineering in KTiOPO4 Canalias, Carlota January 2005 (has links) Ferroelectric crystals are commonly used in nonlinear optics for frequency conversion of laser radiation. The quasi-phase matching (QPM) approach uses a periodically modulated nonlinearity that can be achieved by periodically inverting domains in ferroelectric crystals and allows versatile and efficient frequency conversion in the whole transparency region of the material. KTiOPO4 (KTP) is one of the most attractive ferroelectric non-linear optical material for periodic domain-inversion engineering due to its excellent non-linearity, high resistance for photorefractive damage, and its relatively low coercive field. A periodic structure of reversed domains can be created in the crystal by lithographic patterning with subsequent electric field poling. The performance of the periodically poled KTP crystals (PPKTP) as frequency converters rely directly upon the poling quality. Therefore, characterization methods that lead to a deeper understanding of the polarization switching process are of utmost importance. In this work, several techniques have been used and developed to study domain structure in KTP, both in-situ and ex-situ. The results obtained have been utilized to characterize different aspects of the polarization switching processes in KTP, both for patterned and unpatterned samples. It has also been demonstrated that it is possible to fabricate sub-micrometer (sub-μm) PPKTP for novel optical devices. Lithographic processes based on e-beam lithography and deep UV-laser lithography have been developed and proven useful to pattern sub- μm pitches, where the later has been the most convenient method. A poling method based on a periodical modulation of the K-stoichiometry has been developed, and it has resulted in a sub-μm domain grating with a period of 720 nm for a 1 mm thick KTP crystal. To the best of our knowledge, this is the largest domain aspect-ratio achieved for a bulk ferroelectric crystal. The sub-micrometer PPKTP samples have been used for demonstration of 6:th and 7:th QPM order backward second-harmonic generation with continuous wave laser excitation, as well as a demonstration of narrow wavelength electrically-adjustable Bragg reflectivity. / QC 20100930 quasi-phase matching KTiOPO4 ferroelectric domains atomic force microscopy periodic electric field poling polarization switching second harmonic generation Optical physics Optisk fysik

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