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91	Role of Caveolae in Membrane Tension Köster, Darius Vasco 13 December 2010 (has links) (PDF) Caveolae sind charakteristische Plasmamembraneinstülpungen, die in vielen Zelltypen vorkommen und deren biologische Funktion umstritten ist. Ihre besondere Form und ihre Häu gkeit in Zellen, die stets mechanischen Belastungen ausgesetzt sind, führten zu der Annahme, dass Caveolae die Plasmamembran vor mechanischen Belastungen schützen und als Membranreservoir dienen. Dies sollte mit dieser Dissertation experimentell geprüft werden. Zunächst wurde der Ein uss der Caveolae auf die Membranspannung von Zellen im Normalzustand untersucht. Dann wurden die Zellen mechanisch belastet. Mit Fluoreszensmikroskopie wurde das Verschwinden von Caveolae nach Strecken der Zellen oder nach einem hypo-osmotischen Schock beobachtet. Messungen der Membranspannung vor und unmittelbar nach dem hypo-osmotischem Schock zeigten, dass Caveolae einen Anstieg der Membranspannung verhindern, unabhängig von ATP und dem Cytoskelett. Die Erzeugung von Membranvesikel mit Caveolae erlaubte es, diesen Effekt der Caveolae in einem vereinfachten Membransystem zu beobachten. Schliesslich wurden Muskelzellen untersucht. Zellen, die genetisch bedingt weniger Caveolae haben und mit Muskelschwundkrankheiten in Verbingung stehen, waren mechanisch weniger belastbar als gesunde Zellen. Zusammenfassend wird mit dieser Dissertation die These bestärkt, dass Caveolae einem Anstieg der Membranspannungen entgegenwirken. Dass dies in Zellen und in Vesikeln unabhängig von Energie und Cytoskelett geschieht, lässt auf einen passiven, mechanisch getriebenen Prozess schliessen. Diese Erkenntnis trägt zum Verständnis der Rolle von Caveolae in Zellen bei und kann dem besseren Verständnis von Krankheiten bedingt durch Caveolin-Mutationen, wie z.B. Muskelschwundkrankheiten, dienen. / Caveolae, the characteristic plasma membrane invaginations present in many cells, have been associated with numerous functions that still remain debated. Taking into account the particular abundance of caveolae in cells experiencing mechanical stress, it was proposed that caveolae constitute a membrane reservoir and bu er the membrane tension upon mechanical stress. The present work aimed to check this proposition experimentally. First, the in uence of caveolae on the membrane tension was studied on mouse lung endothelial cells in resting conditions using tether extraction with optically trapped beads. Second, experiments on cells upon acute mechanical stress showed that caveolae serve as a membrane reservoir bu ering surges in membrane tension in their immediate, ATP- and cytoskeleton-independent attening and disassembly. Third, caveolae incorporated in membrane vesicles also showed the tension bu ering. Finally, in a physiologically more relevant case, human muscle cells were studied, and it was shown that mutations with impaired caveolae which are described in muscular dystrophies render muscle cells less resistant to mechanical stress. In Summary the present work provides experimental evidence for the hypothesis that caveolae bu er the membrane tension upon mechanical stress. The fact that this was observed in cells and membrane vesicles in an ATP and cytoskeleton independent manner reveals a passive, mechanically driven process. This could be a leap forward in the comprehension of the role of caveolae in the cell, and in the understanding of genetic diseases like muscular dystrophies. / Cavéoles sont des invaginations caractéristiques de la membrane plas- mique présents dans beaucoup de types cellulaires. Ils sont liées à plusieurs fonctions cellulaires, ce qui sont encore débattues. Prenant compte de l importance des cavéoles dans les cellules soumises au stress mécanique, les cavéoles sont proposées de constituer un réservoir membranaire et de tamponner la tension membranaire pendant des stresses mécaniques. Cette étude a eu le but de tester cette hypothèse expérimentalement. En premier, l in uence des cavéoles sur la tension membranaire au repos a été étudiée sur des cellules endothéliales du poumon de la souris. Puis, on a montré que les cavéoles tamponnent l augmentation de la tension membranaire après l application d un stress mécanique. En suite, la réalisation des vésicules membranaires contenant des cavéoles a permit de montrer leur rôle comme réservoir membranaire dans un système simpli é. Finalement, dans un contexte physiologiquement plus relevant, l étude des cellules musculaires a montrée que les mutations du cavéolin associées aux dystrophies musculaires rendent les cellules moins résistante aux stresses mécaniques. En conclusion, cette étude supporte l\'hypothèse que les cavéoles tamponnent la tension membranaire pendant des stresses mécaniques. Le fait que cela se passe dans les cellules et les vésicules indépendamment d ATP et du cytosquelette révèlent un processus passif et mécanique. Cela pourrait servir à une meilleure compréhension du rôle des cavéoles dans la cellule et les maladies génétiques comme les dystrophies musculaires. Plasmamembran Membranspannung Caveolae Optische Falle Vesikel Caveola plasma membrane membrane tension optical tweezers osmotic shock TIRF vesicle micropipette ddc:530 Plasma Membran Optische Pinzette
92	Experimental study of the kinetics of two systems : DNA complexation by the NCp7 protein and probe dynamics in a glassy colloidal suspension Klajner, Piotr 11 May 2012 (has links) (PDF) In the first part of this thesis, we study the kinetics of the complexation of a double-stranded DNA byNCp7 protein. To do this, we study the evolution of mechanical properties of DNA and its complexation by stretching the DNA/NCp7 complex with a optical trap. We observed that the persistence length of the complex decreases progressively during the complexation. Using astatistical model we describe the evolution of the flexibility of DNA complexed with NCp7. Our main result is that the fraction phi of base pairs that have reacted is not a linear function of time at low phi.We interpret our results assuming that the adsorption of NCp7 on DNA is highly cooperative. In the second chapter, we describe the dynamics of probe particles in a colloidal glassy suspension of Laponite. Laponite is a colloidal discoidal particle of 25 nm in diameter and 0.92 nm thick. We take advantage of evanescent wave microscopy, and follow the movement of fluorescent latex particles.Then we image these particles. We show that for a movement that has a single characteristic time scale, it is simply a linear function of time. We find that, what ever their size, the motion of probe particles can be described by a succession of two dynamic modes, where the fastest mode corresponds to the diffusion of particles in a viscoelastic fluid. [CHIM:OTHE] Chemical Sciences/Other [CHIM:OTHE] Chimie/Autre Single molecule Real time Optical tweezers Optical trap TIRFM
93	From single to many atoms in a microscopic optical dipole trap Fuhrmanek, Andreas 23 September 2011 (has links) (PDF) This thesis focuses on the manipulation of rubidium 87 atoms in a microscopic optical dipole trap. The experiments are performed in various regimes where the number of atoms in the microscopic trap ranges from exactly one atom to several thousands on average.The single atom regime allows us to calibrate the experimental setup. We use it a quantum bit, which state we can prepare and read out with efficiencies of 99.97% and 98.6%, respectively. When several atoms are loaded in the microscopic trap we observe a sub-Poissonian distribution of the number of atoms due to light-assisted collisions in the presence of near-resonant light. A study of these collisions in our particular case (microscopic trap) reveals extremely high loss rates approaching the theoretical Langevin limit. Finally, we demonstrate that the loading of the microscopic trap is more efficient when we superimpose on this trap a second macroscopic trap, which we use as an atom reservoir. This reservoir allows us to load the micro trap from the macro trap in the absence of any near-resonant light, thus avoiding light-assisted collisions.The loading of the micro trap from the macro trap leads to optimal initial conditions for forced evaporation towards Bose-Einstein condensation with about ten atoms only. After evaporation we reach phase-space densities approaching the degenerate regime. [PHYS:QPHY] Physics/Quantum Physics [PHYS:QPHY] Physique/Physique Quantique Atomic physics Quantum information Single atoms Mesoscopic systems Optical tweezers Bose-Einstein condensation Light-assisted collisions Dipole trap
94	Interaction of XMAP215 with a Microtubule Plus-end Studied with Optical Tweezers Trushko, Anastasiya 23 July 2012 (has links) (PDF) Microtubules are a part of the cell cytoskeleton that performs different functions, such as providing the mechanical support for the shape of a cell, acting as tracks along which the motor protein move organelles from one part of the cell to another, or the forming mitotic spindle during the cell division. The microtubules are dynamic structures, namely they can grow and shrink. The phase of microtubule growth alternates with the phase of shrinkage that results in the dynamic microtubule network in the cell. However, to form stable and spatially well-defined structures, such as a mitotic spindle, the cell needs to control this stochastic process. This is done by microtubule-associated proteins (MAPs). One class of MAPs is the proteins of XMAP216/Dis1 family, which are microtubule polymerases. The founding member of this family is X. laevis XMAP215. XMAP215 is a processive polymerase acting on the microtubule plus end. XMAP215 binds either directly or reaches the microtubule plus end by the diffusion along the microtubule lattice. Being at the microtubule plus-end XMAP215 stays there transiently and helps to incorporate up to 25 tubulin dimers into microtubule lattice before it dissociates and, therefore, it processively tracks the growing microtubule end during polymerization. There are two hypothesis of microtubule assembly promotion: (i) XMAP215 repeatedly releases an associated tubulin dimer into the microtubule growing plus end or (ii) structurally stabilizes a polymerized tubulin intermediate at the growing plus end and, therefore, preventing depolymerization events. The first way results into the increase of on-rate of tubulin dimers at the microtubule end, whereas the second way results into the decrease of off-rate of tubulin dimers at the microtubule end. Here, I show the study of the mechanism of microtubule growth acceleration by XMAP215 and the dependence of XMAP215 polymerization activity on the applied force. To answer these questions, I investigated the addition of tubulin dimers to the plus end of the microtubule by XMAP215 and how this addition depends on the applied force. XMAP215 remains at the microtubule end for several rounds of tubulin addition surfing both growing and shrinking microtubule ends. Therefore, if one could track the position of the XMAP215 molecules at the very tip of a microtubule with sufficient resolution, it would provide the information about the dynamics of the microtubule end. The technique, which can detect the position of the object of interest with high spatial and temporal resolution in addition to being able to exert a force, is an optical trap. A calibrated optical trap not only provides a good measure of displacement but also enables force measurements. To monitor the position of the molecules of interest, the molecules of interest are usually attached to a microsphere. Hence, I tethered XMAP215 to a microsphere held by an optical trap, and used XMAP215 as a handle to interact with the microtubule tip. When the microtubule grows, the XMAP215 coated microsphere will move in the optical trap and this movement can be detected with high temporal and spatial resolution. My work demonstrates that cooperatively working XMAP215 molecules can not only polymerize microtubule but also harness the energy of microtubule polymerization or depolymerization to transport some cargo. There is an evidence that orthologues of XMAP215 in budding yeasts, fission yeasts and Drosophila localize on the kinetochores. Therefore, the ability of the bearing some load during microtubule polymerization could be potentially important for the XMAP215 functioning during cell division. I also showed the influence of external force applied to the XMAP215 molecules. Pointing toward microtubule growth, a force of 0.5 pN applied to the microtubule tip-coupled XMAP215-coated microsphere increases XMAP215 polymerization activity. However, the force of the same magnitude but applied against microtubule growth does not affect XMAP215 polymerization activity. This result can be explained by the fact, that the force acting in the direction of microtubule growth constrains XMAP215 to be at the very microtubule tip. Hence, XMAP215 can not diffuse away from plus-end and there is higher chance to incorporate tubulin dimers into the microtubule plus-end. The on- and off-rate of tubulin dimers at the microtubule end are both decreased when the external force applied either in direction of microtubule growth or opposite to it. The external force affects the off-rate slightly stronger than on-rate of tubulin dimer. Taking together, my study gives new insights into the mechanism of microtubule polymerization by XMAP215 and shows some novel properties of this protein. Mikrotubuli XMAP215 Cytoskelett dynamische Instabilität Generierung der Kraft microtubule XMAP215 microtubule dynamic instability microtubule force generation XMAP215 optical tweezers ddc:570 rvk:WE 2400
95	Propriétés rhéologiques des globules rouges / Rheological properties of Red Blood Cells Brust, Matthias 28 June 2013 (has links) Dans cette thèse, les propriétés rhéologiques du sang sont étudiées suivant deux approches differentes. Les propriétés de l'écoulement du plasma sont analysées selon trois modes différents : sous cisaillement, en extension et en constriction. Jusqu'à présent, le plasma était considéré comme un fluide newtonien, et le comportement complexe du sang était simplement attribué à la présence des globules rouges. Les expériences menées ont montré un comportement visco-élastique du plasma, que doit désomais être pris en compte dans les études futures. La deuxième axe traite des globules rouges. Leur assemblage en agrégats rectilignes est à l'origine du comportement rhéofluidifiant, mais les causes de la formation des agrégats restent encore vagues. L'énergie d'interaction entre deux cellules et la distribution des tailles des clusters dans des canaux microfluidiques ont été mesurées en présence de dextran et de fibrinogène. Comme les agrégats sont normalement cassés à des taux de cisaillement élevés, on a cru qu'ils ne jouaient pas de rôle dans l'écoulement du sang. Mais le fait que le nombre de clusters augmente à des concentrations physiologiques de fibrinogène, même pour des taux de cisaillement correspondant à ceux du système microvasculaire, il est clair que l'agrégation ne peut pas être négligée dans la description de l'écoulement du sang en le réseau capillaire. / In this work, the rheological properties of human blood are investigated by two different approaches. The flow properties of plasma, the liquid component of blood, is analyzed under three different conditions: shear flow, elongational flow and contraction flow. Up to now, the plasma was considered as a Newtonian fluid, while the non-Newtonian properties of blood were only attributed to the red blood cells. The performed experiments reveal a viscoelastic behavior of the plasma which has to be considered in future studies. In addition to the plasma, also diluted polymer solutions are analyzed in order to find a good model solution for plasma. The second part concerns the red blood cells. Their adhesion to linear aggregates is held responsible for the well-known shear thinning behavior of blood but the reason for the cluster formation is still not clear. The interaction energy between two red blood cells and the distribution of different sized clusters flowing through narrow channels are measured under the influence of the two macromolecules dextran and fibrinogen. As the aggregates are actually broken at high shear rates, the current understanding is that they would not play a role for the properties of blood flow. However, an increased amount of clusters at physiological fibrinogen concentrations can be shown, even at shear rates which are common in the microvascular system, which clarifies that the aggregation cannot be neglected in the description of blood flow through the capillary network. Globules rouges Module élastique Pinces optiques Écoulements confiné Interactions hydrodynamiques Red blood cell Elastic modulus Optical tweezers Flow in narrow channels Hydrodynamic interactions
96	Ferramenta biofotônica integrada para manipulações e microscopias confocais / Integrates biophotonic tool for manipulations and confocal microscopies Thomaz, André Alexandre de, 1980- 21 December 2007 (has links) Orientador: Carlos Lenz Cesar / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Fisica Gleb Wataghin / Made available in DSpace on 2018-08-11T10:58:51Z (GMT). No. of bitstreams: 1 Thomaz_AndreAlexandrede_M.pdf: 10062018 bytes, checksum: 1e19c55cb5a4e709c2015e2d90f3ac13 (MD5) Previous issue date: 2007 / Resumo: A pesquisa em fotônica biomedica está claramente tomando a direção do entendimento de processos biológicos a nível celular. A resolução necessária para atingir esse objetivo requer praticamente ferramentas fotônicas. Contudo, uma integração de diferentes ferramentes fotônicas e uma aproximação funcional serão necessárias para acessar os processos biomecânicos e bioquímicos celulares. Deste modo nós podemos observar eventos bioquímicos disparados mecanicamente ou eventos mecânicos disparados bioquimicamente, ou até mesmo observar simultâneamente eventos biomecânicos e bioquímicos disparados por outros meios, entre outros, eletricamente. Uma das grandes vantagens das ferramentas fotônicas é a sua facilidade de integração. Nós desenvolvemos uma ferramenta integrada incorporando pinça óptica simples com Microscopia Confocal "Single-photon" e Multifóton. O sistema consegue realizar microscopias de fluorescência excitada pela absorção de dois fótons e geração de segundo harmônico em conjunto com manipulações ópticas. Medidas de força, elasticidade e viscosidade de membranes esticadas podem ser monitoradas em tempo real pelas microscopias confocais, bem como protozoários capturados opticamente, como, por exemplo, Trypanosoma cruzi. Nós mostraremos vários exemplos do uso de tal ferramenta integrada e seu potencial para observar processos mecânicos e bioquímicos a nível celular / Abstract: The research in biomedical photonics is clearly evolving in the direction of the understanding of biological processes at the cell level. The spatial resolution to accomplish this task practically requires photonics tools. However, an integration of different photonic tools and a multimodal and functional approach will be necessary to access the mechanical and biochemical cell processes. This way we can observe mechanicaly triggered biochemical events or biochemicaly triggered mechanical events, or even observe simultaneously mechanical and biochemical events triggered by other means, e.g. electricaly. One great advantage of the photonic tools is its easiness for integration. Therefore, we developed such integrated tool by incorporating single Optical Tweezers with Confocal Single and Multiphoton Microscopies. This system can perform 2-photon excited fluorescence and Second Harmonic Generation microscopies together with optical manipulations. Force, elasticity and viscosity measurements of stretched membranes can be followed by real time confocal microscopies. Also opticaly trapped living protozoas, such as Trypanosoma cruzi. Integration with CARS microscopy is under way. We will show several examples of the use of such integrated instrument and its potential to observe mechanical and biochemical processes at cell level / Mestrado / Física / Mestre em Física Microscopia confocal Microscopia confocal multifóton Pinças óticas Imagens óticas Confocal microscopy Multiphoton confocal microscopy Second harmonic generation microscopy Optical tweezers Optical images
97	Vývoj cell-sorter systému s využitím optické pinzety a mikrofluidních čipů / Development of cell sorter system using optical tweezers and microfluid chips Novák, Pavel January 2011 (has links) In this master thesis I have been dealt with the design and construction of an instrumental platform that used positioning focused laser beam (so-called optical tweezers) for manipulation with living cells without their damage.
98	Řízení a vyhodnocení laserových mikromanipulačních experimentů / Controlling and Evaluation of Laser Micromanipulation Experiments Kaňka, Jan January 2012 (has links) This work is focused on the development of a user friendly software interface using the LabViewTM environment that simplifies running of various experiments using laser micromanipulations and laser microspectroscopy of living microorganisms. Both techniques have been developing very fast for the last decade and belong to the growing group of contact-less and nondestructive techniques for manipulation and diagnostics of individual living microorganisms, cells, or viruses. Within this project we mastered the driving of peripheries, calibration of CCD scene, real-time image processing of the CCD scene, automatic selection of the cell for further laser processing, acquisition and processing of the Raman spectrum from living microorganisms. The final goal of our activity is fully automatic laser-based sorter of living cells depending on their chemical compositions. This work has been elaborated at the Institute of Scientific Instruments of the ASCR, v.v.i. under the supervision of prof. Pavel Zemanek.
99	Měření extinkčních spekter opticky zachycených plazmonických nanočástic / Measurement of extinction spectra of optically trapped plasmon nano-particles Flajšmanová, Jana January 2015 (has links) This thesis deals with the dark-field imaging and the optical spectroscopy of optically trapped plasmonic nanoparticles. The optical trapping and the characterization of a single particle or multiple nanoparticles as well are demonstrated. The number of the optically trapped particles can be estimated from the dark-field scattering intensity. Experiments show the presence of the interparticle coupling among trapped metallic nanoparticles which has not been observed in case of dielectric particles. The scattering spectra of the plasmonic nanoparticles were compared with theoretical models based on the Mie theory and the Discrete dipole approximation.
100	Einzelmolekül-Kraftspektroskopie zur Untersuchung der Wechselwirkungen zwischen Tau-Peptiden und monoklonalen Antikörpern Stangner, Tim 11 March 2015 (has links) In dieser Dissertation werden die Bindungseigenschaften von Rezeptor-Ligand-Komplexen mit Hilfe von Optischen Pinzetten untersucht. Aufgrund ihrer außerordentlichen Orts- (2nm) und Kraftauflösung (0,2pN) ist es möglich, diese spezifischen Interaktionen anhand einzelner Bindungsereignisse zu charakterisieren. Als Modellsysteme dienen die Wechselwirkungen zwischen den phosphorylierungsspezifischen, monoklonalen Antikörpern HPT-101 und HPT-104 und dem Morbus Alzheimer relevanten Tau-Peptid. Dieses pathogen veränderte Peptid wird krankheitsspezifisch an den Aminosäuren Threonin231 und Serin235 phosphoryliert, sodass die Detektion dieses Phosphorylierungsmusters mit Hilfe von monoklonalen Antikörpern eine mögliche Früherkennung der Alzheimer-Krankheit darstellt. Eine notwendige Voraussetzung dafür ist jedoch die exakte Kenntnis der Bindungsstellen des Liganden am Rezeptor. Ziel des ersten Teils dieser Arbeit ist es, das Epitop des monoklonalen Antikörpers HPT-101 zu bestimmen. Dazu werden mögliche bindungsrelevante Aminosäuren durch ein Alanin ausgetauscht (Alanin-Scan) und so insgesamt sieben neue Tau-Isoformen aus dem ursprünglichen doppelt-phosphorylierten Peptid Tau[pThr231/pSer235] hergestellt. Die jeweiligen Interaktionen zwischen den modifizierten Peptiden und dem Antikörper werden mit der dynamischen Kraftspektroskopie untersucht und mit Hilfe eines literaturbekannten Modells analysiert. Die sich daraus ergebenden Bindungsparameter (Lebensdauer der Bindung, charakteristische Bindungslänge, freie Aktivierungsenergie und Affinitätskonstante) werden zusammen mit den relativen Bindungshäufigkeiten erstmals genutzt, um Kriterien für essentielle, sekundäre und nicht-essentielle Aminosäuren im Tau-Peptid zu definieren. Bemerkenswerterweise existieren für insgesamt drei dieser Parameter (Bindungslebensdauer, Bindungslänge und Affinitätskonstante) scharfe Klassengrenzen, mit denen eine objektive Einteilung des Epitops von Antikörper HPT-101 möglich ist. Die erhaltenen Ergebnisse sind in überzeugender Weise im Einklang mit ELISA-Messungen zu diesem Antikörper-Peptid-Komplexen, sie liefern jedoch einen tieferen Einblick in die Natur einer spezifischen Bindung, da den kraftspektroskopischen Messungen auch die Bindungskinetik zugänglich ist. Das zweite Projekt der vorliegenden Dissertation etabliert eine Methodik, um die Datenvarianz in der Bestimmung der relativen Bindungshäufigkeit zu reduzieren. Anhand einer Kombination aus Fluoreszenz- und kraftspektroskopischen Messungen werden die Wechselwirkungen zwischen dem monoklonalen Antikörper HPT-104 und dem fluoreszenzmarkierten Peptid Tau[Fl-pThr231] untersucht. Es wird gezeigt, dass durch Vorsortieren der Peptid-beschichteten Kolloide, entsprechend ihrer Oberflächenbeladung, die Datenvarianz in den Bindungshäufigkeitsmessungen signifikant reduziert wird. info:eu-repo/classification/ddc/530 ddc:530

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