Global ETD Search

21	Structural studies of microbubbles and molecular chaperones using transmission electron microscopy Härmark, Johan January 2016 (has links) Ultrasound contrast agents (CAs) are typically used in clinic for perfusion studies (blood flow through a specific region) and border delineating (differentiate borders between tissue structures) during cardiac imaging. The CAs used during ultrasound imaging usually consist of gas filled microbubbles (MBs) (diameter 1-5 μm) that are injected intravenously into the circulatory system. This thesis partially involves a novel polymer-shelled ultrasound CA that consists of air filled MBs stabilized by a polyvinyl alcohol (PVA) shell. These MBs could be coupled with superparamagnetic iron oxide nanoparticles (SPIONs) in order to serve as a combined CA for ultrasound and magnetic resonance imaging. The first three papers (Paper A-C) in this thesis investigate the structural characteristic and the elimination process of the CA. In Paper A, two types (PVA Type A and PVA Type B) of the novel CA were analyzed using transmission electron microscopy (TEM) images of thin sectioned MBs. The images demonstrated that the SPIONs were either attached to the PVA shell surface (PVA Type A) or embedded in the shell (PVA Type B). The average shell thickness of the MBs was determined in Paper B by introducing a model that calculated the shell thickness from TEM images of cross-sectioned MBs. The shell thickness of PVA Type A was determined to 651 nm, whereas the shell thickness of PVA Type B was calculated to 637 nm. In Paper C, a prolonged blood elimination time was obtained for PVA-shelled MBs compared to the lipid-shelled CA SonoVue used in clinic. In addition, TEM analyzed tissue sections showed that the PVA-shelled MBs were recognized by the macrophage system. However, structurally intact MBs were still found in the circulation 24 h post injection. These studies illustrate that the PVA-shelled MBs are stable and offer large chemical variability, which make them suitable as CA for multimodal imaging. This thesis also involves studies (Paper D-E) of the molecular chaperones (Hsp21 and DNAJB6). The small heat shock protein Hsp21 effectively protects other proteins from unfolding and aggregation during stress. This chaperone ability requires oligomerization of the protein. In Paper D, cryo-electron microscopy together with complementary structural methods, obtained a structure model which showed that the Hsp21 dodecamer (12-mer) is kept together by paired C-terminal interactions.The human protein DNAJB6 functions as a very efficient suppressor of polyglutamine (polyQ) and amyloid-β42 (Aβ42) aggregation. Aggregation of these peptides are associated with development of Huntington’s (polyQ) and Alzheimer’s (Aβ42) disease. In Paper E, a reconstructed map of this highly dynamic protein is presented, showing an oligomer with two-fold symmetry, indicating that the oligomers are assembled by two subunits. / <p>QC 20160527</p> Transmission electron microscopy Contrast agent Microbubble Polyvinyl alcohol Single particle analysis Heat shock protein Molecular chaperone
22	High-sensitivity tracking of optically trapped particles in gases and liquids : observation of Brownian motion in velocity space Kheifets, Simon 22 September 2014 (has links) The thermal velocity fluctuations of microscopic particles mediate the transition from microscopic statistical mechanics to macroscopic long-time diffusion. Prior to this work, detection methods lacked the sensitivity necessary to resolve motion at the length and time scales at which thermal velocity fluctuations occur. This dissertation details two experiments which resulted in velocity measurement of the thermal motion of dielectric microspheres suspended by an optical trap in gases and liquids. First, optical tweezers were used to trap glass microspheres in air over a wide range of pressures and a detection system was developed to track the trapped microspheres' trajectories with MHz bandwidth and <100 fm/rt(Hz) position sensitivity. Low-noise trajectory measurements allowed for observation of fluctuations in the instantaneous velocity of a trapped particle with a signal to noise ratio (SNR) of 26 dB, and provided direct verification of the equipartition theorem and of the Maxwell-Boltzmann velocity distribution for a single Brownian particle. Next, the detection technology was further optimized and used to track optically trapped silica and barium titanate glass microspheres in water and acetone with >50 MHz bandwidth and <3 fm/rt(Hz) sensitivity. Brownian motion in a liquid is influenced by hydrodynamic, time-retarded coupling between the particle and the fluid flow its motion generates. Our measurements allowed for instantaneous velocity measurement with an SNR of up to 16 dB and confirmed the Maxwell Boltzmann distribution for Brownian motion in a liquid. The measurements also revealed several unusual features predicted for Brownian motion in the regime of hydrodynamic coupling, including faster-than-exponential decay of the velocity autocorrelation function, correlation of the thermal force and non-zero cross-correlation between the particle's velocity and the thermal force preceding it. / text Physics Optical tweezers Brownian motion Instantaneous velocity Single particle tracking Microspheres Liquids Gases Hydrodynamic interactions
23	Single particle tracking as a tool to investigate the dynamics of integrated membrane complexes in vivo Robson, Alex J. January 2012 (has links) The last decade has seen substantial advances in single-molecule tracking methods with nano-metre level precision. A powerful tool in single-molecule tracking is fluorescence imaging. One particular application, total internal reflection microscopy, can capture biological processes at high contrast video rate imaging at the single-particle level. This thesis presents methodologically novel methods in analysing single particle tracking data. Presented here is an application of a Bayesian statistical approach that can discriminate between the different diffusive modes that appear with the presence of membrane architecture. This algorithm is denoted BARD; a Bayesian Analysis to Ranking Diffusion. These algorithms are applied to a total internal fluorescence microscopy based experimental data of a novel membrane probe in Escherichia coli. This probe is a plasmid expressed, non-native membrane integrating trans-membrane helix and thus acts as an ideal protein based probe under no specific native control. Two experiments were performed using a combination of varying helix probe size and growth temperature experiments effectively altering the transition temperature of the membrane. These data are suggestive of a passive partitioning of the helix protein into mobile and immobile domains that emerge from the underlying phase behaviour of the membrane. 539.72
24	Automontagem de filamentos de septinas estudada por microscopia eletrônica / Self-assembling of septine filaments studied by electron microscopy Mendonça, Déborah Cezar 06 March 2018 (has links) Septinas são GTPases consideradas como um novo componente do citoesqueleto. Essas proteínas interagem entre si para formar heterocomplexos filamentosos e estruturas de alta ordem que são importantes para a citocinese e uma variedade de outros processos celulares. Existem muitos aspectos mecânicos dessas proteínas que não são totalmente compreendidos, incluindo a forma como os heterocomplexos se agrupam corretamente. Em humanos, há 13 genes que codificam septinas, classificadas em quatro grupos quanto à similaridade em relação à estrutura primária. O complexo hexamérico SEPT7-SEPT6-SEPT2-SEPT2-SEPT6-SEPT7 foi o melhor caracterizado, com uma estrutura cristalina resolvida à 4 Å. Segundo às Regras de Kinoshita, as septinas desse complexo podem ser substituídas nesse arranjo por outras pertencentes ao mesmo grupo. Neste trabalho utilizamos a técnica de microscopia eletrônica de transmissão com análise de partícula única para estudar dois complexos de septinas. Um dos complexos estudados neste projeto é formado por septinas humanas, para as quais atualmente não há informações estruturais disponíveis. O complexo SEPT5-SEPT6-SEPT7 foi expresso heterólogamente em E. coli e purificado em alta concentração salina para evitar a polimerização. A análise de partículas únicas de imagens por contrastação negativa mostrou a presença de partículas alongadas de aproximadamente 25 nm de comprimento, compostos por seis monômeros, como esperado. Com o objetivo de localizar a posição da SEPT5 no complexo, foi realizada uma fusão com MBP (Maltose Binding Protein) e imunomarcação com anticorpo monoclonal anti-SEPT5, concluindo que a SEPT5 está localizada na extremidade do complexo hexamérico. Porém, a SEPT5 pertence ao mesmo grupo da SEPT2, que foi relatada estar localizada no centro do hexâmero. Este resultado possibilitou uma nova discussão sobre a maneira que as septinas formam os complexos e, como a sensibilidade à concentração salina está relacionada com a fragilidade da interface NC, análogo ao observado em complexos de Saccharomyces cerevisiae. Um complexo de Ciona intestinalis incluindo a SEPT2, SEPT6, SEPT7 e SEPT9, também expresso heterólogamente em E. coli, foi preparado por contrastação negativa. A análise de partícula única das imagens coletadas mostrou um heterocomplexo aparentemente hexamérico, embora fosse esperado um octâmero devido à presença das quatro septinas diferentes, sendo uma pertencente à cada um dos quatro grupos. Os resultados deste trabalho proporcionaram um avanço na compreensão da formação de heterocomplexos de septinas e como essas proteínas interagem umas com as outras nesta montagem. / Septins are GTPases that appear to be a novel component of the cytoskeleton. These proteins interact with each other to form filamentous heterocomplexes and high order structures which are important for cytokinesis and a variety of other cellular processes. There are many mechanistic aspects of these proteins that are not fully understood, including how the heterocomplexes correctly assemble. In humans, there are 13 genes encoding septins, classified in four groups based on primary structure. The SEPT7-SEPT6-SEPT2-SEPT2-SEPT6-SEPT7 hexameric complex was the best characterized, with a crystalline structure solved at 4 Å. According to Kinoshita´s Rules, the septins of this complex can be replaced in this arrangement by others belonging to the same group. In this work, we used transmission electron microscopy with single particle analysis to study two septin complexes. One of the complexes studied in this project is composed of three human septins, for which there is currently no structural information available. The SEPT5-SEPT6-SEPT7 complex was heterologously expressed in E. coli and purified at high salt concentration to avoid polymerization. Single particle analysis of negatively stained samples showed the presence of elongated particles of approximately 25 nm in length. To locate SEPT5 in the complex, a fusion with MBP (Maltose Binding Protein) and immunoblotting with anti-SEPT5 monoclonal antibody was performed, concluding that SEPT5 is located at the end of the hexameric complex. However, SEPT5 belongs to the same group as SEPT2, which was reported to be located in the center of the hexamer. This result allowed for a new discussion on the way that septins form heterocomplexes and also, on how the sensitivity of the NC interface in related to salt concentration, analogous to that observed in the heterocomplex of Saccharomyces cerevisiae. A Ciona intestinalis complex including SEPT2, SEPT6, SEPT7 and SEPT9, also expressed heterologously in E. coli, was prepared by negative staining. The single particle analysis of the collected images showed an apparently hexameric heterocomplex, although an octamer was expected due to the presence of the four different septins, one belonging to each of the four groups. The results of this work represent advances in the understanding of the formation of septin heterocomplexes and how these proteins interact with each other during assembly. Análise de partícula única Microscopia eletrônica de transmissão Septinas Septins Single particle analysis Transmission electron microscopy
25	An Automated Analysis Of Single Particle Tracking Data For Proteins That Exhibit Multi Component Motion. Ali, Rehan 01 January 2018 (has links) Neurons are polarized cells with dendrites and an axon projecting from their cell body. Due to this polarized structure a major challenge for neurons is the transport of material to and from the cell body. The transport that occurs between the cell body and axons is called Axonal transport. Axonal transport has three major components: molecular motors which act as vehicles, microtubules which serve as tracks on which these motors move and microtubule associated proteins which regulate the transport of material. Axonal transport maintains the integrity of a neuron and its dysfunction is linked to neurodegenerative diseases such as, Alzheimer’s disease, Frontotemporal dementia linked to chromosome 17 and Pick’s disease. Therefore, understanding the process of axonal transport is extremely important. Single particle tracking is one method in which axonal transport is studied. This involves fluorescent labelling of molecular motors and microtubule associated proteins and tracking their position in time. Single particle tracking has shown that both, molecular motors and microtubule associated proteins exhibit motion with multiple components. These components are directed, where motion is in one direction, diffusive, where motion is random, and static, where there is no motion. Moreover, molecular motors and microtubule associated proteins also switch between these different components in a single instance of motion. We have developed a MATLAB program, called MixMAs, which specializes in analyzing the data provided by single particle tracking. MixMAs uses a sliding window approach to analyze trajectories of motion. It is capable of distinguishing between different components of motion that are exhibited by molecular motors and microtubule associated proteins. It also identifies transitions that take place between different components of motion. Most importantly, it is not limited by the number of transitions and the number of components present in a single trajectory. The analysis results provided by MixMAs include all the necessary parameters required for a complete characterization of a particle’s motion. These parameters are the number of different transitions that take place between different components of motion, the dwell times of different components of motion, velocity for directed component of motion and diffusion coefficient for diffusive component of motion. We have validated the working of MixMAs by simulating motion of particles which show all three components of motion with all the possible transitions that can take place between them. The simulations are performed for different values of error in localizing the position of a particle. The simulations confirm that MixMAs accurately calculates parameters of motion for a range of localization errors. Finally, we show an application of MixMAs on experimentally obtained single particle data of Kinesin-3 motor. Data Analysis Kinesin Motors Matlab Particle Motion Single Particle Tracking Tau Protein Neuroscience and Neurobiology
26	Erosion-corrosion of 304 stainless steel Mohammadi, Farzad 06 1900 (has links) Stainless steel is one of the most commonly used materials in most industries. Excellent corrosion resistance of stainless steel is due to the formation of an oxide film on the surface (passive film), which protects the material from continuous corrosion attacks. When subjected to an attack combining corrosion and erosion, the passive film is damaged and thus, higher and unpredictable degradation rates are observed, which may result in costly consequences. In the first part of this study a model was developed for erosion enhanced corrosion of 304 stainless steel. A new device was designed and constructed, which made possible the impingement of single particles on the surface of sample material at different impact velocities and angles. Based on the electrochemical response of material to the impact of single particles, a model was proposed that considered the number of the impacting particles on the surface. The predictions made by this model were later compared with the results of a slurry jet experiment, which was used to simulate the service conditions. The second part of the research included the basic mechanical and electrochemical studies of the interactions occurring between the particle and material surface during the particle impact. This included the effects of different impact parameters such as coefficient of friction, impact angle, impact energy and particle angular velocity on depassivation of 304 stainless steel and its erosion-corrosion. A depassivation mechanism was proposed that considered a combined effect of the friction force and its effective path of action on the surface. In the last part improving the erosion-corrosion properties of 304 stainless steel was tried based on the results of the second part of the study. Samples were cold rolled and the effect of hardness on the coefficient of friction was investigated, which in the second part was proven responsible for the depassivation of the surface. It was found that the coefficient of friction between the particles and the surface remains unchanged in different applied percentages of cold work. Also it was shown that work hardening is an effective method for increasing the resistance of the material to erosion-corrosion. / Materials Engineering erosion corrosion stainless steel friction single particle impact cold work kinetic energy
27	Ultrafast Coherent X-ray Diffractive Nanoimaging R. N. C. Maia, Filipe January 2010 (has links) X-ray lasers are creating unprecedented research opportunities in physics,chemistry and biology. The peak brightness of these lasers exceeds presentsynchrotrons by 1010, the coherence degeneracy parameters exceedsynchrotrons by 109, and the time resolution is 105 times better. In theduration of a single flash, the beam focused to a micron-sized spot has the samepower density as all the sunlight hitting the Earth, focused to a millimetresquare. Ultrafast coherent X-ray diffractive imaging (CXDI) with X-ray lasers exploitsthese unique properties of X-ray lasers to obtain high-resolution structures fornon-crystalline biological (and other) objects. In such an experiment, thesample is quickly vaporised, but not before sufficient scattered light can berecorded. The continuous diffraction pattern can then be phased and thestructure of a more or less undamaged sample recovered% (speed of light vs. speed of a shock wave).This thesis presents results from the first ultrafast X-ray diffractive imagingexperiments with linear accelerator-driven free-electron lasers and fromoptically-driven table-top X-ray lasers. It also explores the possibility ofinvestigating phase transitions in crystals by X-ray lasers. An important problem with ultrafast CXDI of small samples such as single proteinmolecules is that the signal from a single measurement will be small, requiringsignal enhancement by averaging over multiple equivalent samples. We present anumerical investigation of the problems, including the case where samplemolecules are not exactly identical, and propose tentative solutions. A new software package (Hawk) has been developed for data processing and imagereconstruction. Hawk is the first publicly available software package in thisarea, and it is released as an open source software with the aspiration offostering the development of this field. XFEL Phasing Image Reconstruction Single Particle Imaging Ultrafast Diffraction X-ray diffraction Coherent Diffractive Imaging CXDI
28	Strong Coupling of Gold Nanoparticle Plasmons on Quasi One-Dimensional Assemblies Slaughter, Liane 16 September 2013 (has links) Single particle microscopy and spectroscopy strategies reveal hidden relationships between the surface plasmon resonances (SPRs) and the sizes, shapes, and arrangements of gold nanoparticles (Au NPs). The SPR, the coherent oscillation of the conduction electrons, leads to intense absorption and scattering of light at frequencies satisfying the resonance condition determined by the size, shape, and spacings between NPs. Growing and assembling NPs through wet chemistry yields a diversity of geometries. Together, optical spectroscopy, scanning electron microscopy (SEM), and computational modeling of individual NPs and NP assemblies elucidate the resulting variety of SPRs. Strong coupling of the SPRs in linear assemblies provokes particular interest for tunable structures that will benefit surface enhanced spectroscopies and optical computing. The influence of the constituents and imperfections in such assemblies, which deviate from idealized model systems, must be established one assembly at a time. This thesis demonstrates previously unknown and sensitive relationships between the SPRs and these geometric parameters through systematic single particle experiments of self-assembled ring superstructures, nanorod dimers, individual nanorods populating different size regimes, and short linear chains of Au NPs through single particle spectroscopy. Dark-field scattering of self-assembled ring superstructures of 40 nm Au NPs reveals new plasmon modes that are redshifted from the single NP SPR by hundreds of nanometers, highly polarized along the axis of alignment, and indifferent to irregularities in the NP arrangement. SPRs of Au nanorod dimers, however, are dramatically altered by NP size heterogeneity, reduced symmetry, and metallic contact, consistent with previous studies of small assemblies. Broad band single particle extinction measurements of individual Au nanorods and short chains of 200-1000 nm long demonstrate the importance of the overall dimensions of an NP or an assembly of NPs. Finally, extinction measurements of these chains provide a compelling comparison to chemical polymers via the redshifting of the lowest energy SPR, tolerance to disorder, and the influence of the repeat unit. This result extends already well-defined analogies between plasmonic assemblies and chemical molecules to the ‘plasmonic polymer’. The findings presented in this thesis bring deeper and more detailed understanding to the tunable optical properties of real NP assemblies. gold nanoparticle plasmon single particle spectroscopy plasmon coupling linear assembly superradiant dark-field scattering
29	Erosion-corrosion of 304 stainless steel Mohammadi, Farzad Unknown Date No description available. erosion corrosion stainless steel friction single particle impact cold work kinetic energy
30	Biological Insights from Single-Particle Tracking in Living Cells Sanamrad, Arash January 2014 (has links) Single-particle tracking is a technique that allows for quantitative analysis of the localization and movement of particles. In this technique, trajectories are constructed by determining and connecting the positions of individual particles from consecutive images. Recent advances have made it possible to track hundreds of particles in an individual cell by labeling the particles of interest with photoactivatable or photoconvertible fluorescent proteins and tracking one or a few at a time. Single-particle tracking can be used to study the diffusion of particles. Here, we use intracellular single-particle tracking and trajectory simulations to study the diffusion of the fluorescent protein mEos2 in living Escherichia coli cells. Our data are consistent with a simple model in which mEos2 diffuses normally at 13 µm2 s−1 in the E. coli cytoplasm. Our approach can be used to study the diffusion of intracellular particles that can be labeled with mEos2 and are present at high copy numbers. Single-particle tracking can also be used to determine whether an individual particle is bound or free if the free particle diffuses significantly faster than its binding targets and remains bound or free for a long time. Here, we use single-particle tracking in living E. coli cells to determine the fractions of free ribosomal subunits, classify individual subunits as free or mRNA-bound, and quantify the degree of exclusion of bound and free subunits separately. We show that, unlike bound subunits, free subunits are not excluded from the nucleoid. This finding strongly suggests that translation of nascent mRNAs can start throughout the nucleoid, which reconciles the spatial separation of DNA and ribosomes with co-transcriptional translation. We also show that, after translation inhibition, free subunit precursors are partially excluded from the compacted nucleoid. This finding indicates that it is active translation that normally allows ribosomal subunits to assemble on nascent mRNAs throughout the nucleoid and that the effects of translation inhibitors are enhanced by the limited access of ribosomal subunits to nascent mRNAs in the compacted nucleoid. single-particle tracking intracellular diffusion nucleoid exclusion transcription-translation coupling antibiotics

Search results