Global ETD Search

101	Investigating the effect of membrane anchoring on photoinduced electron transfer pyrazoline based fluorescent probes Hofmekler, Jonathan 18 November 2011 (has links) Fluorescence microscopy is a powerful analytical tool for visualizing biological processes at the subcellular level. In this regard, 1,3,5-triarylpyrazoline based fluorescent probes which act as "turn-on" probes, have been extensively researched. These probes achieve their fluorescence "turn-on" response by inhibition of fluorescence quenching by acceptor-excited photoinduced electron transfer upon binding of an analyte. It has been recently shown that some fluorescent probes used in biological research form colloids composed of nanoparticles, due to their hydrophobic character. This hydrophobic character can also lead to partitioning of the probe into cellular membranes. Colloid formation and membrane partitioning may affect the probes' photophysical properties such as absorption and emission wavelength and quantum yields. Recently, a series of 1,3,5-triarylpyrazolines synthesized in our group by M. T. Morgan, showed no formation of aggregates in aqueous buffer. Surprisingly, these probes increased their fluorescence intensity in the presence of liposomes. The photoinduced electron transfer process is greatly affected by the polarity of the medium in which the probe is used. In this study, the effect of membrane proximity on the photoinduced electron transfer process for pyrazoline based "turn-on" probes has been investigated. A series of water soluble 1,3,5-triarylpyrazolines have been synthesized in which a N,N-dialkylaniline moiety acts as an electron donor and a proton acceptor and an alkylated sulfonamide moiety acts as a molecular anchor for interaction with neutral and anionic liposomes. Pyrazoline Liposomes Photoinduced electron transfer Fluorescence Fluorescent probes Fluorescence microscopy Transition metals Metal ions
102	A molecular snapshot of charged nanoparticles in the cellular environment Fleischer, Candace C. 02 April 2014 (has links) Nanoparticles are promising platforms for biomedical applications ranging from diagnostic tools to therapeutic delivery agents. During the course of these applications, nanoparticles are exposed to a complex mixture of extracellular serum proteins that nonspecifically adsorb onto the surface. The resulting protein layer, or protein "corona," creates an interface between nanoparticles and the biological environment. Protecting the nanoparticle surface can reduce protein adsorption, but complete inhibition remains a challenge. As a result, the corona, rather than the nanoparticle itself, mediates the cellular response to the nanoparticle. The following dissertation describes the fundamental characterization of the cellular binding of charged nanoparticles, interactions of protein-nanoparticle complexes with cellular receptors, and the structural and thermodynamic properties of adsorbed corona proteins. Nanoparticle Protein corona Cellular receptors Serum proteins Opsonization Fluorescence microscopy Circular dichroism spectroscopy Isothermal titration calorimetry
103	Spectroscopic and calorimetric studies of aggregated macromolecules Kitts, Catherine Carter, 1979- 28 August 2008 (has links) Different optical and calorimetric techniques were utilized to gain a better understanding of aggregated macromolecules. This research looked at two different macromolecules: poly(9,9'-dioctylfluorene), a conjugated polymer that forms aggregates in organic solvents; and bovine insulin, which forms amyloid fibrils. Conjugated polymers are of increasing interest due to their thermal stability and ease of solution processing for use in devices. A member of the polyfluorene family, poly(9,9'-dioctylfluorene) (PFO), has been studied due to its blue-emitting spectral properties. However, PFO has been found to form aggregates in solution, which is detected by the presence of a red-shifted absorption peak. This peak is caused when a section of the backbone planarizes forming the [beta]-phase. The [beta]-phase can be removed from the solution upon heating and will not return until the solution is cooled, making it a non-equilibrium process. The dissolution and reformation of the -phase were monitored using absorption spectroscopy and differential scanning calorimetry. Atomic force microscopy (AFM) and near-field scanning optical microscopy (NSOM) were able to probe the aggregates in films. It is important to understand polymer properties in solution in order to understand film morphology. Amyloid fibrils contribute to over 20 different neurodegenerative diseases, in which cures have yet to be found. The fibrils form when a soluble protein misfolds and self-assembles to form insoluble protein aggregates, and the cause of the fibril formation in vivo has still yet to be determined. Spectroscopy studies have been made possible with the use of fluorescent dyes: thioflavin T (ThT), BTA-2, and Congo red (CR). These dyes bind to amyloid fibrils and exhibit changes in their spectral properties. However, the exact mechanism for the binding of these dyes has only recently been studied. Through the use of calorimetry, the forces involved with binding of ThT and CR to amyloid fibrils can be determined. Absorption and fluorescence spectroscopy techniques were employed to study the spectral properties of these dyes. Polarized NSOM was used to determine the ThT or BTA-2's orientation with an individual fibril. Understanding how these dyes bind to fibrils will enable researchers to use spectroscopy to study the early stages of fibril formation. / text Conjugated polymers Conjugated polymers--Spectra Amyloid Insulin Fluorescence spectroscopy Calorimetry Scanning probe microscopy Fluorescence microscopy
104	A model system for understanding the distribution of fines in a paper structure using fluorescence microscopy / Ett modellsystem för att förstå fördelningen av fines i en pappersstruktur med hjälp av fluorescensmikroskopi Jansson Rådberg, Weronica January 2015 (has links) Fines have a very important role in paper chemistry and are a determinant in retention, drainage and the properties of paper. The purpose of this project was to be able to label the fines with fluorophores and study their Brownian motion with fluorescence microscopy. When succeeded this could then be used to study fines, fibers and other additives in a suspension thus giving the fundamental knowledge of why fines have this important role. Due to aggregation of the fines no Brownian motion could be detected. Instead the fines were handled as a network system and small fluorescence labeled latex particles were then studied in this system. This approach yields information about the fines when the obstacle with sedimentation of the network is resolved. / Fines har en viktig roll i papperskemin och har en avgörande roll när det gäller retention, dränering och papprets egenskaper. Syftet med detta projekt var att kunna färga in fines med fluoroforer och sedan följa deras brownska rörelse med hjälp av ett fluorescensmikroskop. Denna metod skulle sedan kunna användas för att observera interaktionerna mellan fines, fibrer och andra additiver i en suspension. Det skulle göra de underliggande mekanismerna kända för varför fines utgör en så viktig del i processen. På grund av att fines aggregerade så fick man istället behandla dem som ett nätverk där man tillsatte redan fluorescerande prober vars rörelser studerades. Att studera fines indirekt på detta vis kommer att ge information när sedimenteringen av nätverket är löst. fines fluorescence microscopy paper chemistry Brownian motion latex particles fines fluorescensmikroskopi papperskemi brownsk rörelse latexpartiklar
105	Superresolution Nonlinear Structured Illumination Microscopy By Stimulated Emission Depletion Zhang, Han January 2014 (has links) The understanding of the biological processes at the cellular and subcellular level requires the ability to directly visualize them. Fluorescence microscopy played a key role in biomedical imaging because of its high sensitivity and specificity. However, traditional fluorescence microscopy has a limited resolution due to optical diffraction. In recent years, various approaches have been developed to overcome the diffraction limit. Among these techniques, nonlinear structured illumination microscopy (SIM) has been demonstrated a fast and full field superresolution imaging tool, such as Saturated-SIM and Photoswitching-SIM. In this dissertation, I report a new approach that applies nonlinear structured illumination by combining a uniform excitation field and a patterned stimulated emission depletion (STED) field. The nature of STED effect allows fast switching response, negligible stochastic noise during switching, low shot noise and theoretical unlimited resolution, which predicts STED-SIM to be a better nonlinear SIM. After the algorithm development and the feasibility study by simulation, the STED-SIM microscope was tested on fluorescent beads samples and achieved full field imaging over 1 x 10 micron square at the speed of 2s/frame with 4-fold improved resolution. Our STED-SIM technique has been applied on biological samples and superresolution images with tubulin of U2OS cells and granules of neuron cells have been obtained. In this dissertation, an effort to apply a field enhancement mechanism, surface plasmon resonance (SPR), to nonlinear STED-SIM has been made and around 8 time enhancement on STED quenching effect was achieved. Based on this enhancement on STED, 1D SPR enhanced STED-SIM was built and 50 nm resolution of fluorescence beads sample was achieved. Algorithm improvement is required to achieve full field superresolution imaging with SPR enhanced STED-SIM. The application of nonlinear structured illumination in two photon light-sheet microscopy is also studied in this dissertation. Fluorescent cellular imaging of deep internal organs is highly challenging because of the tissue scattering. By combining two photon Bessel beam light-sheet microscopy and nonlinear SIM, 3D live sample imaging at cellular resolution in depth beyond 200 microns has been achieved on live zebrafish. Two-color imaging of pronephric glomeruli and vasculature of zebrafish kidney, whose cellular structures located at the center of the fish body are revealed in high clarity. light-sheet microscopy Nonlinear Stimulated emission depletion Structured illumination Superresolution Fluorescence microscopy Optical Sciences
106	Dynamic Contrast-Enhanced Magnetic Resonance Imaging & Fluorescence Microscopy of Tumor Microvascular Permeability Jennings, Dominique Louise January 2008 (has links) Microvascular permeability is a pharmacologic indicator of tumor response to therapy, and it is expected that this biomarker will evolve into a clinical surrogate endpoint and be integrated into protocols for determining patient response to antiangiogenic or antivascular therapies. The goal of this research is to develop a method by which microvascular permeability (Ktrans) and vascular volume (vp) as measured by DCE-MRI were directly compared to the same parameters measured by intravital fluorescence microscopy in an MRI-compatible window chamber model. Dynamic contrast enhanced-MRI (DCE-MRI) is a non-invasive, clinically useful imaging approach that has been used extensively to measure active changes in tumor microvascular hemodynamics. However, uncertainties exist in DCE-MRI as it does not interrogate the contrast reagent (CR) itself, but the effect of the CR on tissue water relaxivity. Thus, direct comparison of DCE-MRI with a more quantitative measure would help better define the derived parameters. The combined imaging system was able to obtain both dynamic contrast-enhanced MRI data high spatio-termporal resolution fluorescence data following injection of fluorescent and gadolinium co-labeled albumin. This approach allowed for the cross-validation of vascular permeability data, in relation tumor growth, angiogenesis and response to therapy in both imaging systems. dynamic contrast enhanced-MRI intravital fluorescence microscopy microvascular permeability vascular volume dorsal midline skinfold window chamber
107	Homo-FRET Imaging of CEACAM1 in Living Cells using Total Internal Reflection Fluorescence Polarization Microscopy Lo, Jocelyn 20 November 2012 (has links) Carcinoembryonic antigen-related cell adhesion molecule 1 (CEACAM1) undergoes homotypic and heterotypic cis- and trans- interactions that regulate processes including metabolism, immune response, and tumorigenesis. To better understand and eventually control CEACAM1’s numerous roles, we characterized the localization, homotypic cis-oligomerization, and regulation of CEACAM1 at the molecular scale using steady-state TIRFPM homo-FRET imaging in living cells. We established the anisotropy sensitivity of our TIRFPM platform using Venus monomers and dimers, which had significantly different anisotropy values. Heterogeneously distributed across the plasma membrane, CEACAM1-4L-EYFP was a mixture of monomers and oligomers, with a slightly more monomeric population at the high intensity regions. In addition, perturbation with ionomycin or α-CEA pAb increased CEACAM1 monomers, potentially in a localized manner. Although limited in detecting any anisotropy differences between CEACAM1-4L-EYFP and monomeric G432,436L-CEACAM1-4L-EYFP populations, TIRFPM homo-FRET imaging can be a useful tool for studying membrane protein self-association with proper controls and studies that focus on relative anisotropy changes. Fluorescence polarization microscopy CEACAM1 Oligomerization 0541
108	Proliferation of Pathogenic Biofilms within Sealer-root Dentin Interfaces is Affected by Sealer Type and Aging Period Roth, Karina Adriana 20 December 2011 (has links) Objective: To assess biofilm proliferation within the sealer-dentin interfaces of methacrylate resin-based sealers, self-etch (SE) and total-etch (TE), and an epoxy resin-based sealer (EP). Methods: Standardized human root specimens were filled with the test materials and were aged for 1 week, 1, 3 or 6 months in saline (n=3/group). Monoclonal biofilms of Enterococcus faecalis were grown on the specimens for 7 days in continuous media reactor. The extent of biofilm proliferation of E. faecalis within the sealer-dentin interface for each material at each incubation period was assessed using fluorescence microscopy of dihydroethidium-stained specimens. Results: TE had less biofilm proliferation than EP and SE (p<0.01). Deeper biofilm proliferation was detected in SE and EP specimens aged for 1 and 3 months than those aged for 1 week or 6 months (p<0.05). Conclusion: Self-etch and epoxy resin-based sealers were more susceptible to interfacial biofilm proliferation than total-etch system at shorter incubation periods. Dentistry 0567
109	The function, characterization of expression, localization and activity of a divergent ice nucleating protein from Pseudomonas borealis Vanderveer, Tara Lynn 15 May 2012 (has links) An ice nucleating protein (INP) with 66% amino acid sequence identity to the better-known INP of Pseudomonas syringae has been described in an environmental isolate of P. borealis and designated InaPb. Despite the fact that INPs are classified as ice-binding proteins, InaPb showed little affinity for pre-formed ice and showed incorporation rates similar to Ina- strains. Additionally, it appeared to lack in the ability to shape ice or limit its growth. However, it was an effective ice nucleator. Using the coding sequence for InaPb and a green fluorescent protein tag (GFP), an InaPb-GFP fusion protein construct was inserted into a broad host expression vector in order to visualize the expression and localization of the protein in E. coli and an Ina- strain of P.syringae. The InaPb-GFP protein appears to localize at the poles of E. coli, but the nucleation temperature for these cells was only marginally above -9°C, which indicated poor nucleation activity. When expressed in Ina- P. syringae, the proteins showed clustering throughout the cell and an increased ability to nucleate ice following cold conditioning. The ability to nucleate ice was further increased by the removal of the GFP tag resulting in an average nucleation temperature more consistent with that seen in the native host P. borealis. Since inaPb transcript levels did not appear to change after cold conditioning, the clustering seen using fluorescence microscopy was likely the result of increased aggregation of protein in the membrane. Most INP- producing bacteria are associated with plant disease, but experiments with P. borealis suggested that the Ina+ phenotype was not indicative of pathogenicity in this strain. It is hoped that my contribution to the functional characterization of this INP will lead to a better understanding of these special proteins and their importance to the handful of bacteria that exhibit this activity. / Thesis (Master, Biology) -- Queen's University, 2012-05-15 09:55:52.506 Ice nucleating protein Ice binding proteins Ice affinity Fluorescence microscopy Pseudomonas borealis
110	Homo-FRET Imaging of CEACAM1 in Living Cells using Total Internal Reflection Fluorescence Polarization Microscopy Lo, Jocelyn 20 November 2012 (has links) Carcinoembryonic antigen-related cell adhesion molecule 1 (CEACAM1) undergoes homotypic and heterotypic cis- and trans- interactions that regulate processes including metabolism, immune response, and tumorigenesis. To better understand and eventually control CEACAM1’s numerous roles, we characterized the localization, homotypic cis-oligomerization, and regulation of CEACAM1 at the molecular scale using steady-state TIRFPM homo-FRET imaging in living cells. We established the anisotropy sensitivity of our TIRFPM platform using Venus monomers and dimers, which had significantly different anisotropy values. Heterogeneously distributed across the plasma membrane, CEACAM1-4L-EYFP was a mixture of monomers and oligomers, with a slightly more monomeric population at the high intensity regions. In addition, perturbation with ionomycin or α-CEA pAb increased CEACAM1 monomers, potentially in a localized manner. Although limited in detecting any anisotropy differences between CEACAM1-4L-EYFP and monomeric G432,436L-CEACAM1-4L-EYFP populations, TIRFPM homo-FRET imaging can be a useful tool for studying membrane protein self-association with proper controls and studies that focus on relative anisotropy changes. Fluorescence polarization microscopy CEACAM1 Oligomerization 0541

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