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

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

Superresolution Nonlinear Structured Illumination Microscopy By Stimulated Emission Depletion

Zhang, Han

January 2014

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

Dynamic Contrast-Enhanced Magnetic Resonance Imaging & Fluorescence Microscopy of Tumor Microvascular Permeability

Jennings, Dominique Louise

January 2008

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

Homo-FRET Imaging of CEACAM1 in Living Cells using Total Internal Reflection Fluorescence Polarization Microscopy

Lo, Jocelyn

20 November 2012

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

Proliferation of Pathogenic Biofilms within Sealer-root Dentin Interfaces is Affected by Sealer Type and Aging Period

Roth, Karina Adriana

20 December 2011

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

The function, characterization of expression, localization and activity of a divergent ice nucleating protein from Pseudomonas borealis

Vanderveer, Tara Lynn

15 May 2012

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

Homo-FRET Imaging of CEACAM1 in Living Cells using Total Internal Reflection Fluorescence Polarization Microscopy

Lo, Jocelyn

20 November 2012

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

Proliferation of Pathogenic Biofilms within Sealer-root Dentin Interfaces is Affected by Sealer Type and Aging Period

Roth, Karina Adriana

20 December 2011

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

Contributions to 3D Image Analysis using Discrete Methods and Fuzzy Techniques : With Focus on Images from Cryo-Electron Tomography

Gedda, Magnus

January 2010

With the emergence of new imaging techniques, researchers are always eager to push the boundaries by examining objects either smaller or further away than what was previously possible. The development of image analysis techniques has greatly helped to introduce objectivity and coherence in measurements and decision making. It has become an essential tool for facilitating both large-scale quantitative studies and qualitative research. In this Thesis, methods were developed for analysis of low-resolution (in respect to the size of the imaged objects) three-dimensional (3D) images with low signal-to-noise ratios (SNR) applied to images from cryo-electron tomography (cryo-ET) and fluorescence microscopy (FM). The main focus is on methods of low complexity, that take into account both grey-level and shape information, to facilitate large-scale studies. Methods were developed to localise and represent complex macromolecules in images from cryo-ET. The methods were applied to Immunoglobulin G (IgG) antibodies and MET proteins. The low resolution and low SNR required that grey-level information was utilised to create fuzzy representations of the macromolecules. To extract structural properties, a method was developed to use grey-level-based distance measures to facilitate decomposition of the fuzzy representations into sub-domains. The structural properties of the MET protein were analysed by developing a analytical curve representation of its stalk. To facilitate large-scale analysis of structural properties of nerve cells, a method for tracing neurites in FM images using local path-finding was developed. Both theoretical and implementational details of computationally heavy approaches were examined to keep the time complexity low in the developed methods. Grey-weighted distance definitions and various aspects of their implementations were examined in detail to form guidelines on which definition to use in which setting and which implementation is the fastest. Heuristics were developed to speed up computations when calculating grey-weighted distances between two points. The methods were evaluated on both real and synthetic data and the results show that the methods provide a step towards facilitating large-scale studies of images from both cryo-ET and FM.

digital image analysis

3D

fuzzy

algorithms

grey-weighted distance

region growing

electron tomography

tracing

fluorescence microscopy

Probing the structure of the pericellular matrix via novel biophysical assays

McLane, Louis T.

12 January 2015

The pericellular matrix (PCM) is a voluminous polymer network adhered to and surrounding many different types of mammalian cells, and which extends out into the environment outside the cell for distances ranging up to twenty microns. It is comprised of very long flexible polymers (hyaluronan) which are tethered to the cell surface and which have binding sites for large, highly charged bottle brush proteoglycans (aggrecan). The PCM plays an important role in many cell functions such as cell proliferation, cell adhesion, cell migration, and cancer development, however the precise way it influences these processes remains unclear. Three original biophysical tools are developed in this thesis in order to study the PCM: the quantitative particle exclusion assay (qPEA), optical force probe assay (OFPA), and exogenous fluorescent aggrecan mapping assays. These tools are used to measure the polymeric and biophysical properties of the matrix in order to make further advancements in the understanding the PCMs role in adhesion, transport to and from the cell surface, its purported function as a chemical micro-reservoir, as well as basic studies on the kinetics of its formation, turnover and maintenance. The qPEAs measure the penetration and distribution of sub-micron particles after they diffuse into the cell coat, where their distribution maps the interior structure of the PCM. The qPEA assays reveal that the PCM acts a sieve, separating incoming particles by their size, preventing micron sized particles from entering the PCM while allowing sub 100 nm particles to pass to the cell surface. The OFPA uses an optically-trapped bead to study the force response of the matrix as it encounters the probe. The assay not only reveals new details about the PCM such as the fact that it is larger than initially thought, having a two layer structure, but when combined with a polymer physics model which relates the observed equilibrium forces to an existing osmotic pressure gradient within the PCM, the OFPA studies produce the first discovery and measurement of the correlation length distribution in the cell coat. The OFPA and qPEA assays are also performed on cells modified with exogenous aggrecan, resulting in a model for possible proteoglycan mediated cell coat transformations. The fluorescent exogenous aggrecan assays measure the dynamics of the exogenous aggrecan binding to and releasing from the coat, revealing that the PCM can be rapidly modified by a changing environment, and quantitatively measure how the exogenous aggrecan modifies the existing PCM. Together, these assays provide an unprecedented look into the interior structure of the PCM, and the mechanisms responsible both for this structure and its modification.

Biophysics

PCM

Pericellular matrix

Cell coat

Polymer physics

Physics

Optical trap

Microscopy

Fluorescence microscopy