Global ETD Search

221	Dynamique réactionnelle d'antibiotiques au sein des biofilms de Staphylococcus aureus : apport de la microscopie de fluorescence multimodale / Dynamic reactivity of antibiotics inside Staphylococcus aureus biofilms : contribution of multimodal fluorescence microscopy Daddi Oubekka, Samia 30 January 2012 (has links) Les bactéries forment des communautés spatiales adhérentes à des surfaces, appelées biofilms. Ces organisations bactériennes sont omniprésentes dans les milieux naturel, industriel et médical et peuvent porter atteinte à notre santé lorsqu’elles hébergent des agents pathogènes, parmi lesquels le médiatique Staphylococcus aureus sur lequel a porté l’ensemble de ce travail de thèse. Cette bactérie est l’une des principales causes d’infections chroniques, mais également d’infections nosocomiales, impliquant le plus souvent des biofilms. Il est aujourd’hui reconnu qu’une telle biostructure est un véritable bouclier à l’action des antimicrobiens et à celle du système immunitaire. Outre les résistances génétiques des bactéries pathogènes aux antibiotiques, l’hétérogénéité chimique et biologique de la structure tridimensionnelle des biofilms pourrait être à l’origine de ces phénomènes de tolérance et de chronicité d’infections. C’est à cette problématique que se rattache ce travail de thèse concernant l’action de la vancomycine sur des biofilms de S. aureus. Alors que les connaissances sur la réactivité de cet antibiotique clef avec S. aureus proviennent essentiellement d’études réalisées sur des cellules planctoniques, l’originalité de notre approche a été d’étudier la diffusion-réaction de la vancomycine in situ dans l’épaisseur des biofilms en utilisant en particulier des outils avancés de microscopie de fluorescence (Time-Lapse, FLIM, FRAP, et FCS). Nous avons ainsi évalué sa biodisponibilité dans la matrice d’exopolymères, ainsi que l’impact de la physiologie spécifique des bactéries incluses en biofilms sur l’activité de cet antibiotique, utilisé seul ou en association avec la rifampicine. Cette approche multidisciplinaire a permis une meilleure compréhension des mécanismes impliqués dans la singulière tolérance de ces biostructures à l’action des antibiotiques, et de souligner l’urgence de développer des approches préventives telles que le diagnostic précoce des infections impliquant des biofilms. / Bacteria form architecturally complex communities adherent to surfaces, known as biofilms. These structured living cells are ubiquitous and found in natural, industrial and medical environments. They can affect our health when they host pathogens as the well known Staphylococcus aureus species which constitute the main purpose of this thesis. This bacteria is one of the major causes of chronic and nosocomial infections, most often involving biofilms. It is now recognized that such biostructure is a true shield against the action of antimicrobial agents and the host immune system. In addition to the genetic resistance of pathogenic bacteria to antibiotics, the chemical and biological heterogeneity of biofilms could be the cause of these phenomena of tolerance and apparition of chronic infections. This work aimed at studying of the action of vancomycin on S. aureus biofilms. While the knowledge on the reactivity of this key antibiotic with S. aureus bacteria comes mainly from studies of planktonic cells, the originality of our approach was to study the diffusion-reaction processes of vancomycin in situ in the thickness of biofilms using particularly advanced fluorescence imaging tools (Time-Lapse, FLIM, FRAP and FCS). We thus assess its bioavailability in the exopolymeric matrix, and the impact of the cell physiology of bacteria included in biofilms on the activity of this antibiotic when used alone or in combination with rifampicin. This multidisciplinary approach has allowed a better understanding of the mechanisms involved in the particular tolerance of these biostructures to the action of antibiotics, and underlines the emergency to develop preventive approaches such as early diagnosis of infections involving biofilms. Biofilm Tolérance aux antibiotiques Microscopie de fluorescence Time-lapse FRAP FCS FLIM Biofilm Antibiotics tolerance Fluorescence microscopy Time-lapse FRAP FCS FLIM
222	On the interaction of DNA nanostructures with lipid bilayers Journot, Céline M. A. January 2017 (has links) Much of our knowledge of cellular biology arises from direct observation of active cellular functions. Tools and techniques have steadily developed over the past several hundreds of years to aid in our understanding and control of the nanoworld and are referred to as nanotechnologies. In the context of nanotechnology, DNA is not used as a carrier for genetic information (as it is in cell), but as a construction material. DNA offers unprecedented control over the construction of simplified biomimetic models for the study of biological processes. This thesis first introduces and defines the field of DNA nanotechnology, with particular emphasis on the interaction of snthetic DNA nanostructures with biological membranes. Inspired by the protein clathrin, three-fold symmetric DNA tile made of eight, short DNA strands and capable of polymerising is described and studied, with the aim to interact with and controllably bend a membrane bilayer. This structure presented challenges during construction so an enhanced three-armed DNA structure built with DNA origami was designed. The succesful assembly of a rigid and functionalisable nanostructure is described. This origami structure was polymerised into large constructs in solution and on a supported lipid membrane. The shape of the structure was modulated to vary its curvature and apply a bending force to a lipid vesicle when anchored to it. Following the conclusion of this study, we present the construction of a small, unique DNA structure for enhanced electron microscopy imaging in cell lysate. This project is part of a developing technique to couple the interaction specificity of dyes in super-resolution microscopy and the high-resolution output of electron microscopy. Finally, the optimisation procedures and recommendations for TEM imaging of samples of DNA origami and lipid structures are discussed. 530
223	Laser scanning confocal arthroscopy in orthopaedics : examination of chondrial and connective tissues, quantification of chondrocyte morphology, investigation of matirx-induced autologous chondrocyte implantation and characterisation of osteoarthritis Jones, Christopher Wynne January 2007 (has links) [Truncated abstract] Articular cartilage (AC) covers the surface of synovial joints providing a nearly frictionless bearing surface and distributing mechanical load. Joint trauma can damage the articular surface causing pain, loss of mobility and deformation. Currently there is no uniform treatment protocol for managing focal cartilage defects, with most treatment options targeted towards symptomatic relief but not limiting the progression into osteoarthritis (OA). Autologous chondrocyte implantation (ACI) and more recently matrix-induced autologous chondrocyte implantation (MACI), have emerged as promising methods for producing hyaline or hyaline-like repair tissue, however there remains some controversy regarding the exact histological nature of the tissue formed. Histological characterisation of AC repairs requires destructive tissue biopsy potentially inducing further joint pathology thereby negating the treatment effect. OA is recognised as a major cause of pain, loss of function and disability in Western populations, however the exact aetiology is yet to be elucidated. The assessment of both OA and cartilage repair has been limited to macroscopic observation, radiography, magnetic resonance imaging (MRI) or destructive biopsy. The development of non-destructive AC assessment modalities will facilitate further development of AC repair techniques and enable early monitoring of OA changes in both experimental animal models and clinical subjects. Confocal laser scanning microscopy (CLSM) is a type of fluorescence microscopy that generates high-resolution three-dimensional images from relatively thick sections of tissue. ... Biomechanical analysis suggested that the mechanical properties of MACI tissue remain inferior for at least three months. This study showed the potential of a multi-site sheep model of articular cartilage defect repair and validated its assessment via LSCA. Finally, the LSCA was used to arthroscopically image the cartilage of an intact fresh frozen cadaveric knee from a patient with clinically diagnosed OA. Images were correlated to ICRS (Outerbridge) Grades I-IV and histology. The LSCA gave excellent visualization of cell morphology and cell density to a depth of up to 200'm. Classical OA changes including clustering chondrocytes, surface fibrillation and fissure formation were imaged. Fair to moderate agreement was demonstrated with statistically significant correlations between all modalities. This study confirmed the viability of the LSCA for non-destructive imaging of the microstructure of the OA cartilage. In conclusion, the LSCA identified histological features of orthopaedic tissues, accurately quantified chondrocyte morphology and demonstrated classical OA changes. While the development and investigation of an ovine model of cartilage repair showed the treatment benefit of MACI, some biomechanical issues remain. Ultimately, the LSCA has been demonstrated as a reliable nondestructive imaging modality capable of providing optical histology without the need for mechanical biopsy. Medical Subject Headings (MESH): articular cartilage; autologous chondrocyte implantation; matrix-induced autologous chondrocyte implantation; biomechanics; cartilage; confocal microscopy; diagnosis; histology; image analysis; immunohistochemistry; magnetic resonance imaging; microscopy; osteoarthritis Confocal fluorescence microscopy Articular cartilage Arthroscopy -- Methods Cartilage cells -- Transplantation Orthopedics Histology Articular cartilage Confocal microscopy Osteoarthritis Osteoarthritis Autologous chondrocyte implantation
224	CHARACTERIZATION, CONTROL AND MODELING OF PHASE SEPARATION IN MIXED PHOSPHOLIPID-PERFLUORINATED FATTY ACID MONOLAYERS 2013 May 1900 (has links) The overall objective of this PhD thesis research is to understand and control phase separation in mixed perfluorinated fatty acid-phospholipid surfactant systems that have applications as pulmonary surfactant (PS) mixtures, with an ultimate view of controlling film composition, morphology and mechanical properties. In this context the interaction between perfluorooctadecanoic acid (C18F), 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC), the major component of native PS extract, and 1,2-dipalmitoyl-sn-glycero-3-phosphoglycerol (DPPG) has been explored in Langmuir monolayers and Langmuir–Blodgett (LB) films using a combination of atomic force microscopy (AFM), fluorescence microscopy (FM) and Brewster angle microscopy (BAM) measurements. Thermodynamic and morphological studies of binary and ternary mixed films made of C18F, DPPC and DPPG indicated that both the phospholipids and C18F were miscible over a wide range of compositions. The mixed phospholipid-C18F films contained multimolecular aggregates that were highly enriched in the phospholipids. Furthermore, it was found that the magnitude of the DPPC-C18F interaction could be modulated by altering the concentration of sodium ions in the underlying subphase. Using a highly simplified lung mimic fluid (pH 7.4, 150mM NaCl), DPPC and C18F became fully immiscible. Moreover, the performance characteristics of the mixed films demonstrated the usefulness of C18F as an additive for PS formulations. The effectiveness of a PS protein mimicking peptide was evaluated against DPPC to allow comparison with previous measurements of DPPC-C18F mixed system. The mixing thermodynamics of the peptide and DPPC in Langmuir monolayer implied a repulsive interaction between the film components. The hysteresis response of the mixed monolayer films indicated that the lipid-protein mixture improved the re-spreading of DPPC films. Moreover, molecular-level organization of the mixed films explored by both FM and BAM confirmed the formation of liquid-expanded DPPC domains in the presence of minute amount of the peptide. In order to obtain a thorough understanding of the effect of the deposition process and surfactant tail polarities on the interfacial behavior of perfluorocarbon-hydrocarbon mixed monolayer films, both BAM and AFM measurements of arachidic acid (C20) with perfluorotetradecanoic acid (C14F) and palmitic acid (C16) with C18F mixed monolayer were performed. These measurements revealed that film morphology was minimally perturbed upon its deposition onto solid substrates. Coarse grained molecular dynamics (MD) simulations of films comprised of DPPC molecules with tails of various polarities suggested that the phase separation between the monolayer components could be controlled by varying surfactant tail polarities. Pulmonary lung surfactant Langmuir monolayer Miscibility Phase-separation Dipalmitoyl phosphatidylcholine Perfluorooctadecanoic acid Atomic force microscopy Fluorescence microscopy Brewster angle microscopy
225	Near-Wall Thermometry via Total Internal Reflection Fluorescence Micro-Thermometry (TIR-FMT) Suda-Cederquist, Keith David 26 March 2007 (has links) To effectively design systems of microchannels it is necessary for scientists and engineers to understand thermal transport characteristics of microchannels. To experimentally determine the convective heat transfer coefficient of microchannels it is necessary to measure both the bulk and surface temperature fields. This investigation aims to develop a technique, named Total Internal Reflection Fluorescent Micro-Thermometry (TIR-FMT), to measure the temperature of water within several hundred nanometers of a wall--effectively, the surface temperature of the wall. In TIR-FMT, an evanescent-wave is generated in the water near the wall. The intensity of this evanescent-wave decays exponentially with distance from the wall. A fluorophore if illuminated by the evanescent-wave can absorb a photon. Excited fluorophores subsequently emit red-shifted photons, which are called fluorescence. The probability of a fluorescent emission is temperature-dependent. Therefore, by monitoring the intensity of the fluorescence a correlation can be made to the temperature of the region of illumination. Using the TIR-FMT technique the temperature dependence of the fluorescence intensity from buffered fluorescein (pH=9.2) was determined to be 1.35%/C. TIR-FMT can be used to measure the temperature of a fluorophore solution within 600 nm of a wall across a temperature range of 12.5-55C. The average uncertainties (95% confidence) of the temperature measured was determined to be 2.3C and 1.5C for a single 1.5x1.5 and #956;m pixel and the entire 715x950 and #956;m viewfield. By spatial averaging, average uncertainties of 2.0C and 1.8C were attained with spatial resolutions of 16x16 and 100x100 and #956;m, respectively. Surface temperature Total internal reflection Fluorescence Thermometry Fluorescent TIR-FMT Microchannels Evanescent wave Rhodamine b Fluorescein Temperature measurements Fluorescence microscopy Heat Transmission Microelectronics
226	Self-assembly and Structure Investigation of Recombinant S-layer Proteins Expressed in Yeast for Nanobiotechnological Applications Korkmaz, Nuriye 24 January 2011 (has links) (PDF) In numerous Gram-negative and Gram-positive bacteria as well as in Archaea SL proteins form the outermost layer of the cell envelope. SL (glyco)monomers self-assemble with oblique (p2), tetragonal (p4), or hexagonal (p3, p6) symmetries [12]. SL subunits interact with each other and with the underlying cell surface by relatively weak non-covalent forces such as hydrogen-bonds, ionic bonds, salt-bridges or hydrophobic interactions. This makes them easy to isolate by applying chaotropic agents like urea and guanidine hydrochloride (GuHCl), chelating chemicals, or by changing the pH of the environment [10]. Upon dialysis in an ambient buffer monomers recrystallize into regular arrays that possess the forms of flat sheets, open ended cylinders, or spheres on solid substrates, at air-water intefaces and on lipid films, making them appealing for nanobiotechnological applications [3, 18]. The aim of this study was to investigate the structure, thermal stability, in vivo self-assembly process, recrystallization and metallization of three different recombinant SL proteins (SslA-eGFP, mSbsC-eGFP and S13240-eGFP) expressed in yeast S. cerevisiae BY4741 which could be further used in nanobiotechnological applications. In order to fulfill this aim, I investigated the in vivo expression of SL proteins (SslA, SbsC, S13240) tagged with eGFP (SL-eGFP) in the yeast S. cerevisiae BY4141. First, I characterized the heterologous expression of SL fusion constructs with growth and fluorescence measurements combined with Western blot analyses. Fluorescence microscopy investigations of overnight grown cultures showed that SslA-eGFP fusion protein was expressed as fluorescent patches, mSbsC-eGFP as tubular networks, and S13240-eGFP as hollow-like fibrillar network structures, while eGFP did not show any distinct structure Thermal stability of in vivo expressed SL-eGFP fusion proteins were investigated by fluorescence microscopy and immunodetection. In vivo self-assembly kinetics during mitosis and meiosis was the second main issue. In parallel, association of in vivo mSbsC-eGFP structures with the cellular components was of interest. A network of tubular structures in the cytosol of the transformed yeast cells that did not colocalize with microtubules or the actin cytoskeleton was observed. Time-resolved analysis of the formation of these structures during vegetative growth and sporulation was investigated by live fluorescence microscopy. While in meiosis ascospores seemed to receive assembled structures from the diploid cells, during mitosis surface layer structures were formed de novo in the buds. Surface layer assembly always started with the appearance of a dot-like structure in the cytoplasm, suggesting a single nucleation point. In order to get these in vivo SL assemblies stably outside the cells (in situ), cell distruption experiments were conducted. The tubular structures formed by the protein in vivo were retained upon bursting the cells by osmotic shock; however their average length was decreased. During dialysis, monomers obtained by treatment with chaotropic agents recrystallized again to form tube-like structures. This process was strictly dependent on calcium ions, with an optimal concentration of 10 mM. Further increase of the Ca2+ concentration resulted in multiple non-productive nucleation points. It was further shown that the lengths of the S-layer assemblies increased with time and could be controlled by pH. After 48 hours the average length at pH 9.0 was 4.13 µm compared to 2.69 µm at pH 5.5. Successful chemical deposition of platinum indicates the potential of recrystallized mSbsC-eGFP structures for nanobiotechnological applications. For example, such metalized protein nanotubes could be used in conductive nanocircuit technologies as nanowires. S-Schicht eGFP Hefe Fluoreszenzmikroskopie Rekristallisation Metallisierung Nanobiotechnologie S-layer eGFP Yeast Fluorescence microscopy Recrystallization Metallization Nanobiotechnology ddc:570 rvk:WG 2100
227	Rezeptor-vermittelte Lieferung von Genen durch gezielte Liposomen und Quantum Dots / Receptor mediated gene delivery using targeted liposomes and Quantum Dots Sigot, Valeria 02 July 2008 (has links) No description available. 500 Naturwissenschaften allgemein Mathematics and Computer Science gezielte Liposomen Quantenpunkten konfokale Fluoreszenzmikroskopie EGF-Rezeptor Targeted liposomes Quantum Dots confocal fluorescence microscopy EGF receptor 42.03 WR900 WA310
228	Dynamische Strukturen am Zellcortex: Aktivierbarkeit und Akkumulation von Ezrin in Abhängigkeit von PIP2 / Dynamic structures at the cell cortex: activation and accumulation of ezrin depending on PIP2 Bosk, Sabine 18 March 2011 (has links) No description available. 500 Naturwissenschaften Chemistry Ezrin PIP2 F-Aktin Cytoskelett Quarzmikrowaage Fluoreszenzmikroskopie Ezrin PIP2 F-actin cytoskeleton quartz crystal microbalance fluorescence microscopy Chemie SX 000: Biochemie
229	Entwicklung eines Fusionsassays basierend auf porenüberspannenden Membranen / Development of a fusion assay based on pore-spanning membranes Höfer, Ines 05 July 2011 (has links) No description available. 540 Chemie Chemistry Membranfusion porenüberspannende Membranen FRET Fluoreszenzmikroskopie SICM membrane fusion pore-spanning membranes FRET fluorescence microscopy SICM 35.70 Biochemie: Allgemeines SX 000 Biochemie
230	Single-molecule experiments with mitotic motor proteins / Einzelmolekül-Experimente mit mitotischen Motorproteinen Thiede, Christina 28 September 2012 (has links) No description available. 530 Physik WCC 000 Physics Einzelmolekül-Fluoreszenzmikroskopie TIRF-Mikroskopie mitotische Motorproteine Kinesin-5 Regulation single-molecule fluorescence microscopy TIRF microscopy mitotic motor proteins Kinesin-5 regulation 42.12

Search results