Global ETD Search

71	Tailoring of Biomaterials using Ionic Interactions : Synthesis, Characterization and Application Atthoff, Björn January 2006 (has links) The interactions between polymers and components of biological systems are an important area of interest within the fields of tissue engineering, polymer chemistry, medicine and biomaterials. In order to create such a biomimetic material, it must show the inherent ability to reproduce or elicit a biological function. How do we design synthetic materials in order to direct their interactions with biological systems? This thesis contributes to this research with aspects of how polymers interact with biological materials with the help of ionic interactions. Polyesters, biodegradable or not, may after a hydrolytic cleavage interact ionically with protonated amines by the liberated carboxylate functions. Amines are found in proteins and this fact will help us to anchor proteins to polyester surfaces. Another type of interaction is to culture cells in polymeric materials, i.e. scaffolds. We have been working on compliant substrates, knitted structures, to allow cell culture in three dimensions. A problem that arises here is how to get a high cell seeding efficiency? By working on the interactions between polymers, proteins and finally cells, it is possible to create a polarized protein membrane that allows for very efficient cell seeding, and subsequent three dimensional cell cultures. Finally a synthetic route to taylor interaction was developed. Here a group of polymers known as ionomers were synthesized. In our case ionic end groups have been placed onto biodegradable polycarbonates, we have created amphiphilic telechelic ionomers. Functionalization, anionic or cationic, changes the properties of the material in many ways due to aggregation and surface enrichment of ionic groups. It is possible to add functional groups for a variety of different interactions, for example introducing ionic groups that interact and bind to the complementary charge of proteins or on the other hand one can chose groups to prevent protein interactions, like the phosphorylcholine zwitterionomers. Such interactions can be utilized to modulate the release of proteins from these materials when used in protein delivery applications. The swelling properties, Tg, degradation rate and mechanical properties are among other things that will easily be altered with the choice of functional groups or backbone polymer. Chemistry biodegradable polymers ionomer water uptake protein delivery protein adsorption protein membrane cell seeding efficiency amphiphillic inner structure polarized membrane Kemi
72	Combinatorial Technique for Biomaterial Design Wingkono, Gracy A. 12 July 2004 (has links) Combinatorial techniques have changed the paradigm of materials research by allowing a faster data acquisition in complex problems with multidimensional parameter space. The focus of this thesis is to demonstrate biomaterials design and characterization via preparation of two dimensional combinatorial libraries with chemically-distinct structured patterns. These are prepared from blends of biodegradable polymers using thickness and temperature gradient techniques. The desired pattern in the library is chemically-distinct cell adhesive versus non-adhesive micro domains that improve library performance compared to previous implementations that had modest chemical differences. Improving adhesive contrast should minimize the competing effects of chemistry versus physical structure. To accomplish this, a method of blending and crosslinking cell adhesive poly(季aprolactone) (PCL) with cell non-adhesive poly(ethylene glycol) (PEG) was developed. We examine the interaction between MC3T3-E1 osteoblast cells and PCL-PEG libraries of thousands of distinct chemistries, microstructures, and roughnesses. These results show that cells grown on such patterned biomaterial are sensitive to the physical distribution and phases of the PCL and PEG domains. We conclude that the cells adhered and spread on PCL regions mixed with PEG-crosslinked non-crystalline phases. Tentatively, we attribute this behavior to enhanced physical, as well as chemical, contrast between crystalline PCL and non-crystalline PEG. Protein adsorption Cellular adhesion Cellular response Crystallization Dewetting Phase separation Combinatorial Biomedical materials Design Cell adhesion Combinatorial chemistry Combinatorial designs and configurations Crystallization
73	Adsorptive Immobilisierung von Kollagen Typ I an Titanoxidoberflächen / Adsorptive immobilisation of collagen type I on titanium surfaces Wolf-Brandstetter, Cornelia 12 September 2004 (has links) (PDF) Titanium and titanium alloys are frequently used for implants in bone contact. In some cases (diabetis, osteoporosis) there are requirements for improved osseointegration. Initial reactions after surgery show an important influence on the long time stability of the implants. Newer studies focus on the surface composition of the implants in particular the modification with biological components. Collagen is the main component of bone and is therefore an interesting substance for the base modification of titanium implants. The aim of the work was to investigate the adsorptive immobilisation of collagen type I on titanium surfaces. The influence of different adsorption parameters was studied. Several modified surfaces were characterized in matters of immobilized collagen amount, stability, change of conformation and influence on cell behavior. / Titanimplantate werden aufgrund ihrer ausgezeichneten Volumen- und Oberflächeneigenschaften seit vielen Jahren mit großem Erfolg als Implantatmaterialien im Knochenkontakt eingesetzt. Für bestimmte Patientengruppen, u.a. Diabetiker oder Patienten mit osteoporotischem Knochen, ist ein weitergehend verbessertes Einheilverhalten der Implantate anstrebenswert. Entscheidende Bedeutung für den Einheilprozess sowie für die Langzeitstabilität wird der initialen Reaktion des Körpers unmittelbar nach Implantation zugemessen. Neben zahlreichen Ansätzen, durch Modifizierung der chemischen und morphologischen Eigenschaften der Oberfläche in die Reaktionen des Körpers einzugreifen, rückt in neueren Studien zunehmend die Immobilisierung biologischer Komponenten (Proteine, Peptide, Wachstumsfaktoren) in den Mittelpunkt der Betrachtungen. Die Einbeziehung von Kollagen als Hauptbestandteil der organischen Knochenmatrix stellt daher eine interessante Grundmodifikation dar. Das Ziel dieser Arbeit bestand darin, zu untersuchen, inwieweit durch eine adsorptive Immobilisierung von Kollagen eine stabile und funktionale Beschichtung von Titanoxidoberflächen erzielt werden kann. Da sowohl Tropokollagen als auch fibrilläres Kollagen prinzipiell zur Beschichtung von Titanoberflächen eingesetzt werden können, wurde das Adsorptionsverhalten beider Kollagenformen in bezug auf verschiedene Lösungsparameter untersucht und ausgewählte Zustände hinsichtlich ihrer Stabilität und der Erhaltung der biologischen Funktionalität charakterisiert. Implantate Kollagen Oberflächenmodifizierung Proteinadsorption Titan collagen implants protein adsorption surface modification titanium ddc:540 rvk:VK 8567 Adsorption Implantat Kollagen Modifizierung Oberfläche Titan
74	Wechselwirkung von dünnen Schichten aus HVZ Polyestern im wässrigen Medium mit Modellproteinen Mikhaylova, Yulia 01 May 2006 (has links) (PDF) The dissertation work focuses on the whole route of material development starting from the investigations of properties of the initial (raw) HBPs to their applications. Each research step is given in a separate chapter to enhance attention to various aspects of the aim of the work. Thus, every chapter is started with an introduction. After that, the methods applied and experimental procedure are described. Next part tries to give the comprehensive description of the results obtained. At the end of the chapter, the main points are summarized. The Chapter 1 gives the theoretical description of the main experimental techniques used in this work. In Chapter 2 the chemical (chemical composition, purity, typical structure elements) and physical (glass transition temperature, the temperature of the maximum decomposition, the thermal stability at the high temperatures, molar mass, polydispersity and possible aggregation in solution) properties examined by different techniques of polymer analysis are described. The Chapter 3 is divided into three separate parts: In Chapter 3.1 the description of the formation and modification of inter- and intramolecular hydrogen bonds of hydroxyl terminated HBP is presented to reveal the information of hydroxyl groups re- and/or association due to the high temperatures applied. In Chapter 3.2 the nature of the solid-liquid interface of HBP thin films have been studied by different surface sensitive techniques with respect to further protein adsorption investigations. In Chapter 3.3 the strategy for the fabrication of surface attached carboxyl terminated HBP using &quot;grafting to&quot; technique is developed. The Chapter 4 consists of two parts: The first (theoretic) part outlines the basic principles of protein chemistry, factors influencing on the protein molecule stability in aqueous medium, the mechanism of protein adsorption and forces involved in the adsorption process. In the second part the combination of different in situ techniques was applied to obtain a comprehensive description of complex adsorption processes of protein molecules on different polymer surfaces. HVZ Polyestern Modellproteinen hyperbranched polymers protein adsorption spectroscopic ellipsometry ATR-FTIR spectroscopy ddc:540 rvk:VK 8007 Adsorption Dünne Schicht Polyester Polymere Proteine
75	Multilayer Structures for Biomaterial Applications : Biomacromolecule-based Coatings Halthur, Tobias January 2005 (has links) <p>The cellular response to a biomaterial, such as a dental implant, is mainly governed by the surface properties, and can thus be altered by the introduction of a surface coating. In this thesis the buildup of a biomacromolecule-based coating formed by layerby-layer (LbL) deposition of the charged polypeptides poly(L-lysine) (PLL) and poly(L-glutamic acid) (PGA) has been studied. In an attempt to make these coatings bioactive and useful for bone-anchored implants, an amelogenin protein mixture (EMD), has been immobilized in these thin polyelectrolyte multilayer (PEM) films. Multilayers were also built by LbL deposition of the natural biomacromolecules collagen (Col) and hyaluronic acid (HA). Multilayer films of these two extra-cellular biomacromolecules should be of interest for use as a scaffold for tissue engineering.</p><p>The buildup of the multilayer films has been followed in situ, using ellipsometry, quartz crystal microbalance with dissipation (QCM-D), and dual polarization interferometry (DPI). The studied PLL/PGA multilayers were found to be highly hydrated, and to exhibit a two-regime buildup behavior, with an initial “slow-growing” regime, and a second “fast-growing” regime with a linear growth in film thickness and more than linear growth in mass. A net diffusion of polypeptides into the film during the buildup led to an increase in density of the films for each layer adsorbed. A change in density was also observed in the Col/HA film, where HA penetrated and diffused into the porous fibrous Col network.</p><p>The formed PLL/PGA films were further found to be rather stable during drying, and post-buildup changes in temperature and pH, not losing any mass as long as the temperature was not raised too rapidly. The film thickness responded to changes in the ambient media and collapsed reversibly when dried. A swelling/de-swelling behavior of the film was also observed for changes in the temperature and pH.</p><p>The EMD protein adsorbed to silica surfaces as nanospheres, and could by itself form multilayers. The adsorption of EMD onto PLL/PGA multilayer films increased at lower pH (5.0), and EMD could be immobilized in several layers by alternate deposition of EMD and PGA.</p> multilayer layer-by-layer deposition physical chemistry surface chemistry adsorption ellipsometry QCM-D DPI protein adsorption polypeptides biomaterials biosurfaces amelogenin solid/liquid interface Surface and colloid chemistry Yt- och kolloidkemi
76	Pattern Recognition in Single Molecule Force Spectroscopy Data Paulin, Hilary 05 September 2013 (has links) We have developed an analytical technique for single molecule force spectroscopy (SMFS) data that avoids filtering prior to analysis and performs pattern recognition to identify distinct SMFS events. The technique characterizes the signal similarity between all curves in a data set and generates a hierarchical clustering tree, from which clusters can be identified, aligned, and examined to identify key patterns. This procedure was applied to alpha-lactalbumin (aLA) on polystyrene substrates with flat and nanoscale curvature, and bacteriorhodopsin (bR) adsorbed on mica substrates. Cluster patterns identified for the aLA data sets were associated with different higher-order protein-protein interactions. Changes in the frequency of the patterns showed an increase in the monomeric signal from flat to curved substrates. Analysis of the bR data showed a high level of multiple protein SMFS events and allowed for the identification of a set of characteristic three-peak unfolding events. biophysics single molecule biophysics single molecule force spectroscopy alpha-lactalbumin bacteriorhodopsin pattern recognition hierarchical clustering clustering force spectroscopy protein adsorption protein structure surface curvature atomic force microscopy
77	Mediation of Osteoblast Responses to Titanium Roughness by Adsorbed Proteins Wilson, Cameron January 2005 (has links) Stable fixation of implants such as artificial teeth depends on the direct apposition of bone to the implanted material. While endosseous implants were traditionally allowed to "osseointegrate" over several months without carrying load, clinical and experimental data show that prostheses with roughened surfaces allow successful integration when subject to earlier loading and more challenging implant sites. However, to design implant surfaces for an optimal biological response requires an understanding of the mechanism by which roughened surfaces promote osseointegration. Research into this mechanism has, to date, focussed primarily on the response of osteoblastic cells to surface topography in vitro. While these have demonstrated some consistent trends in cell behaviour, the fundamental means by which cells sense and respond to roughness remain unclear. It has been suggested that cell responses to changes in topography may relate to differences in the proteins adsorbed from serum (in vitro). While experimental evidence indirectly suggests that physical features can affect protein adsorption, few studies have examined this with respect to surface roughness, particularly as a mediator of cell responses. To address this issue, cell culture and protein adsorption experiments were conducted on a limited range of surface textures. Titanium samples were ground to produce morphologically similar surfaces with three grades of roughness. A duplicate set of specimens were heated at 600°C for one hour, with the aim of masking potential variations in physicochemical properties with differing degrees of grinding. Osteoblast attachment and proliferation studies were conducted over a short time-frame of 48 hours or less, to highlight the effects of proteins adsorbed from serum rather than secreted by adherent cells. Gel electrophoresis provided a profile of the proteins adsorbed to each surface after 15 minutes, corresponding to the time by which the cells had settled onto the surface. Finally, confocal microscopy was used to examine cell morphology on each surface, and to visualize specific interactions between cellular structures and adsorbed adhesion-mediating proteins. Although the effects were inconsistent, attachment assays showed some indications that fewer cells attached in the first 90 minutes as roughness increased. This inverse cell number-roughness trend was significant at 48 hours; however, the variability in attachment assays prevented reliable separation of attachment and proliferation rate effects. While the reduction in cell number with increasing roughness is consistent with previous reports, it is typically observed at later time points, and thus may be increasingly confounded by contact inhibition and differentiation. Thermal oxidation of the titanium did not impact on osteoblast responses to roughness, although it significantly slowed cell proliferation. The latter result was unexpected on the basis of previous reports. One-dimensional gel electrophoresis revealed no significant differences in the composition of adsorbed layers with variations in roughness. However, as expected on account of wettability changes, the heat-treatment did correspond to significant changes in the adsorption profile. While this was not a highly sensitive analysis, it suggests that the cell responses to roughness changes were not governed by broadscale differences in the proteins initially available to adhering cells. In addition to the composition of the adsorbed layer, the distribution of proteins may also vary with topography. The immunofluorescence methods were not sufficiently sensitive to reveal the distribution of adsorbed adhesion proteins (vitronectin and fibronectin). However, the lack of clear labelling does suggest an absence of large accumulations due to specific topographic features. Further work is required to address this issue conclusively. Observations of cell morphology were consistent with widely-reported contact guidance phenomena on grooved surfaces, with elongation and alignment (with topography) increasing with groove depth. Cell elongation was also enhanced on the more hydrophilic, heat-treated titanium, but this effect diminished over time. Although increased elongation at 90 minutes corresponded to lower cell numbers at 48 hours, no causal relationship has yet been established. Biomaterials Cell attachment Cell morphology Cell proliferation Cell spreading Fibronectin Heat treatment Osteoblasts Protein adsorption Roughness Surface topography Thermal oxidation Titanium Vitronectin.
78	Wechselwirkung von dünnen Schichten aus HVZ Polyestern im wässrigen Medium mit Modellproteinen Mikhaylova, Yulia 11 May 2006 (has links) The dissertation work focuses on the whole route of material development starting from the investigations of properties of the initial (raw) HBPs to their applications. Each research step is given in a separate chapter to enhance attention to various aspects of the aim of the work. Thus, every chapter is started with an introduction. After that, the methods applied and experimental procedure are described. Next part tries to give the comprehensive description of the results obtained. At the end of the chapter, the main points are summarized. The Chapter 1 gives the theoretical description of the main experimental techniques used in this work. In Chapter 2 the chemical (chemical composition, purity, typical structure elements) and physical (glass transition temperature, the temperature of the maximum decomposition, the thermal stability at the high temperatures, molar mass, polydispersity and possible aggregation in solution) properties examined by different techniques of polymer analysis are described. The Chapter 3 is divided into three separate parts: In Chapter 3.1 the description of the formation and modification of inter- and intramolecular hydrogen bonds of hydroxyl terminated HBP is presented to reveal the information of hydroxyl groups re- and/or association due to the high temperatures applied. In Chapter 3.2 the nature of the solid-liquid interface of HBP thin films have been studied by different surface sensitive techniques with respect to further protein adsorption investigations. In Chapter 3.3 the strategy for the fabrication of surface attached carboxyl terminated HBP using &quot;grafting to&quot; technique is developed. The Chapter 4 consists of two parts: The first (theoretic) part outlines the basic principles of protein chemistry, factors influencing on the protein molecule stability in aqueous medium, the mechanism of protein adsorption and forces involved in the adsorption process. In the second part the combination of different in situ techniques was applied to obtain a comprehensive description of complex adsorption processes of protein molecules on different polymer surfaces. info:eu-repo/classification/ddc/540 ddc:540 HVZ Polyestern, Modellproteinen
79	Adsorptive Immobilisierung von Kollagen Typ I an Titanoxidoberflächen Wolf-Brandstetter, Cornelia 13 July 2004 (has links) Titanium and titanium alloys are frequently used for implants in bone contact. In some cases (diabetis, osteoporosis) there are requirements for improved osseointegration. Initial reactions after surgery show an important influence on the long time stability of the implants. Newer studies focus on the surface composition of the implants in particular the modification with biological components. Collagen is the main component of bone and is therefore an interesting substance for the base modification of titanium implants. The aim of the work was to investigate the adsorptive immobilisation of collagen type I on titanium surfaces. The influence of different adsorption parameters was studied. Several modified surfaces were characterized in matters of immobilized collagen amount, stability, change of conformation and influence on cell behavior. / Titanimplantate werden aufgrund ihrer ausgezeichneten Volumen- und Oberflächeneigenschaften seit vielen Jahren mit großem Erfolg als Implantatmaterialien im Knochenkontakt eingesetzt. Für bestimmte Patientengruppen, u.a. Diabetiker oder Patienten mit osteoporotischem Knochen, ist ein weitergehend verbessertes Einheilverhalten der Implantate anstrebenswert. Entscheidende Bedeutung für den Einheilprozess sowie für die Langzeitstabilität wird der initialen Reaktion des Körpers unmittelbar nach Implantation zugemessen. Neben zahlreichen Ansätzen, durch Modifizierung der chemischen und morphologischen Eigenschaften der Oberfläche in die Reaktionen des Körpers einzugreifen, rückt in neueren Studien zunehmend die Immobilisierung biologischer Komponenten (Proteine, Peptide, Wachstumsfaktoren) in den Mittelpunkt der Betrachtungen. Die Einbeziehung von Kollagen als Hauptbestandteil der organischen Knochenmatrix stellt daher eine interessante Grundmodifikation dar. Das Ziel dieser Arbeit bestand darin, zu untersuchen, inwieweit durch eine adsorptive Immobilisierung von Kollagen eine stabile und funktionale Beschichtung von Titanoxidoberflächen erzielt werden kann. Da sowohl Tropokollagen als auch fibrilläres Kollagen prinzipiell zur Beschichtung von Titanoberflächen eingesetzt werden können, wurde das Adsorptionsverhalten beider Kollagenformen in bezug auf verschiedene Lösungsparameter untersucht und ausgewählte Zustände hinsichtlich ihrer Stabilität und der Erhaltung der biologischen Funktionalität charakterisiert. info:eu-repo/classification/ddc/540 ddc:540
80	Synthesis and Protein Adsorption Studies of Pegylated-Polyester Nanoparticles with Different Peg Architectures Montenegro-Galindo, Gladys Rocio January 2013 (has links) No description available. Polymer Chemistry Polymers Cyclic PEG PEG-b-PCL micelles protein adsorption cyclization self-assembly DLS diblock copolymer amphiphilic polymer fluorescent diblock copolymer rhodamine FCCS, FCS fluorescent micelles

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