Global ETD Search

41	Conception et caractérisation de nouveaux fluorophores organiques de la famille des triazapentalènes : outils pour l'imagerie cellulaire / Design and characterization of new organic fluorophores analogs of triazapentalenes as tools for cellular imaging Sirbu, Doina 20 December 2016 (has links) Au cours du 21ème siècle, les techniques de fluorescence ont montré une expansion considérable dans l’étude du mécanisme du vivant. Un progrès majeur dans le développement, la conception et les applications de divers types de chromophores organiques ont été achevés. Bien que largement utilisés, les sondes fluorescentes les plus utilisées souffrent encore de quelques limitations qui diminuent leur étendue d'action. Les plus problématiques sont : un nombre restreint de familles de chromophores, une faible résistance au photoblanchiment, une faible solubilité aqueuse, une durée de vie de fluorescence relativement courte, etc…. A ce titre, le développement de nouveaux motifs organiques inédits, compacts et possédants des propriétés de fluorescence alternatives et/ou complémentaires aux fluorophores usuels organiques reste plus que jamais d’actualité. Dans ce contexte, les noyaux 1,3a, 6a-triazapentalènes nous sont apparus particulièrement prometteuses et encore très peu exploitées. Dans ce manuscrit, il est décrit la synthèse de noyaux tricycliques et tétracycliques comportant ce motif, obtenus par substitution nucléophiles aromatiques, suivi d’une thermolyse. La modulation de ces noyaux a ensuite été effectuée par couplage métallo-catalysé. L’évaluation photophysique de ces composés révèle des propriétés spectroscopiques remarquables comme des rendements quantiques supérieurs à 50%, des déplacements de Stokes d’environ 100 nm et des longueurs d’ondes d’émission allant de 450 à 650 nm. Le dernier volet de cette thèse a porté sur l’imagerie cellulaire, qui nous a permis d’évaluer les meilleurs fluorophores sur cellules vivantes. / Over the last two decades, fluorescence technologies have shown a spectacular spreading in biological research. Major progress in the development, design, and purposeful application of various types of organic chromophores was achieved. Although widely used, the most commonly fluorescent probes still suffer from some limitations which decrease their use in the field of life sciences. The most problematic ones are: low scaffold diversity, high sensitivity to photobleaching, low water solubility and modest Stokes Shift… In this context, the main idea of our work focuses on the development of novel organic motifs responding to the conventional fluorophores issues. The 1,3a, 6a-triazapentalene moiety represents a real interest in this field with its promising optical properties. In this manuscript, the syntheses of tricyclic and tetracyclic derivatives containing this scaffold were obtained by aromatic nucleophilic substitution followed by the thermolysis cyclization. The modulation of these cores was then allowed by various organometallic cross of these compounds provides remarkable spectroscopic properties, as quantum yields above 50%, Stokes shift around 100 nm, and emission wavelengths between 450 and 650 nm. The last part of this thesis was focused on cellular imaging, that allowed us to evaluate the best fluorophores in living cells. Fluorescence Triazapentalène Photoblanchiment Amphiphile Propriétés photophysiques Imagerie cellulaire Couplages organo-métalliques Thermolyse SNAr Fluorescence Triazapentalène Photobleaching Amphiphile Photophysics properties Organometallic coupling Thermolysis SNAr 547
42	Crumbs Affects Protein Dynamics In Anterior Regions Of The Developing Drosophila Embryo Knust, Elisabeth, Firmino, João, Tinevez, Jean-Yves 18 January 2016 (has links) Maintenance of apico-basal polarity is essential for epithelial integrity and requires particular reinforcement during tissue morphogenesis, when cells are reorganised, undergo shape changes and remodel their junctions. It is well established that epithelial integrity during morphogenetic processes depends on the dynamic exchange of adherens junction components, but our knowledge on the dynamics of other proteins and their dynamics during these processes is still limited. The early Drosophila embryo is an ideal system to study membrane dynamics during morphogenesis. Here, morphogenetic activities differ along the anterior-posterior axis, with the extending germband showing a high degree of epithelial remodelling. We developed a Fluorescence Recovery After Photobleaching (FRAP) assay with a higher temporal resolution, which allowed the distinction between a fast and a slow component of recovery of membrane proteins during the germband extension stage. We show for the first time that the recovery kinetics of a general membrane marker, SpiderGFP, differs in the anterior and posterior parts of the embryo, which correlates well with the different morphogenetic activities of the respective embryonic regions. Interestingly, absence of crumbs, a polarity regulator essential for epithelial integrity in the Drosophila embryo, decreases the fast component of SpiderGFP and of the apical marker Stranded at Second-Venus specifically in the anterior region. We suggest that the defects in kinetics observed in crumbs mutant embryos are the first signs of tissue instability in this region, explaining the earlier breakdown of the head epidermis in comparison to that of the trunk, and that diffusion in the plasma membrane is affected by the absence of Crumbs. info:eu-repo/classification/ddc/610 ddc:610
43	Méthodes optiques d’attribution d’identifiants moléculaires à des cellules uniques pour assurer leur traçabilité Binan, Loïc 05 1900 (has links) No description available. Cellule unique marquage séquençage photoblanchiment tri cellulaire cellule rare cancer single cell labeling sequencing photobleaching cell sorting rare cells
44	Dynamic Chemical Imaging And Analysis Within Biologically Active Materials Alex M Sherman (10711971) 06 May 2021 (has links) A thorough understanding of pharmaceutical and therapeutic products and materials is important for an improved quality of life. By probing the complex behaviors and properties of these systems, new insights can allow for a better understanding of current treatments, improved design and synthesis of new drug products, and the development of new treatments for various health conditions. Often, the impact of these new insights are limited by current technology and instrumentation and by the methods in which existing data is processed. Additionally, current standards for characterization of pharmaceuticals and therapeutics are time-consuming and can delay the timeline in which these products become available to the consumer. By addressing the limitations in current instrumentation and data science methods, faster and improved characterization is possible.<div><br></div><div>Development and improvement in optical instrumentation provides potential solutions to the current limitations of characterization methods by conventional instrumentation. Limitations in speed can be addressed through the use of nonlinear optical (NLO) methods, such as second harmonic generation (SHG) and two-photon excited ultraviolet fluorescence (TPE-UVF) microscopy, or by linear methods such as fluorescence recovery after photobleaching (FRAP). For these methods, a high signal-to-noise ratio (SNR) and a nondestructive nature decrease the overall sample size requirements and collections times of these methods. Furthermore, by combination of these optical techniques with other techniques, such as thermal analysis (e.g. differential scanning calorimetry (DSC)), polarization modulation, or patterned illumination, the collection of more complex and higher quality data is possible while retaining the improved speed of these methods. Thus, this modified instrumentation can allow for improved characterization of properties such as stability, structure, and mobility of pharmaceutical and therapeutic products.<br></div><div><br></div><div>With an increase in data quantity and complexity, improvements to existing methods of analysis, as well as development of new data science methods, is essential. Machine learning (ML) architectures and empirically validated models for the analysis of existing data can provide improved quantification. Using the aforementioned optical instrumentation, auto-calibration of data acquired by SHG microscopy is one such method in which quantification of sample crystallinity is enabled by these ML and empirical models. Additionally, ML approaches utilizing generative adversarial networks (GANs) are able to improve on identification of data tampering in order to retain data security. By use of GANs to tamper with experimentally collected and/or simulated data used in existing spectral classifiers, knowledge of adversarial methods and weakness in spectral classification can be ascertained. Likewise, perturbations in physical illumination can be used to ascertain information on classification of real objects by use of GANs. Use of this knowledge can then be used to prevent further data tampering or by improving identification of data tampering.<br></div> Nonlinear optical microscopy Polarization dependence Image Analysis Adversarial attacks Instrumentation
45	Sélection visuelle basée sur un phénotype migratoire, isolation et caractérisation de cellules uniques métastatiques Desjardins-Lecavalier, Nicolas 11 1900 (has links) La caractérisation d’échantillons biologiques s’effectue très souvent au microscope optique. Or, il est techniquement difficile d’isoler quelques cellules rares parmi une culture hétérogène en se basant strictement sur des caractéristiques observables au microscope, comme la localisation, la morphologie ou le déplacement, car il n’existe pas nécessairement de marqueur moléculaire unique qui leur sont associés. Afin de répondre à cet enjeux, le laboratoire dans lequel j’ai effectué mon stage de maîtrise a récemment développé la Single Cell Magneto Optical Capture (scMOCa), qui utilise des réactifs communs et un laser de faible puissance pour attacher des billes ferromagnétiques à la membrane plasmique cellulaire et permet d’isoler magnétiquement les cellules d’intérêt. Le présent ouvrage rapporte l’application de la scMOCa à la migration de cellules métastatiques ainsi que les adaptations apportées à la technique nécessaires à la réalisation du projet. Notamment, le volume de cellules uniques capturé a été augmenté d’un facteur d’environ 250 grâce à l’automatisation de la technique et à l’étude du photoblanchiement de la fluorescéine, phénomène à la base de la scMOCa. Brièvement, l’expérience consiste à capturer les cellules uniques présentant les phénotypes migratoires les plus importants, définis par l’analyse de leur trajectoire, parmi une culture hétérogène de cellules métastatique. Les résultats de l’expérience démontrent une conservation des phénotypes migratoires après plusieurs mitoses. Aussi, l’expression génétique relative fait ressortir des gènes et groupes de gènes propres à la migration cellulaire. / The characterization of biological samples depends heavily on the optical microscope. However, it is technically challenging to isolate rare cells among a heterogeneous culture solely based on visual inspection at the microscope. Indeed, characteristics like location, morphology or displacement do not necessairly have specific related molecular markers. In order to solve this issue, the laboratory where I accomplished my master internship developped the Single Cell Magneto Optical Capture (scMOCa) wich uses commun reagents and a low powered laser to attach ferromagnetic beads on the cell plasma membrane and isolate the cells of interest with magnetic tools. The present work reports the application of scMOCa to the metastatic cell migration and the implemented adaptations to the technique in order to carry out the project, especially by increasing the number of single cells being isolated by a factor of 250. This adaptation requiered the study of photobleaching, phenomenon at the foundation of scMOCa. Briefly, the experiment consists to capture the cells presenting the most important migratory phenotypes, defined by their track analysis, among a heterogeneous metastatic cell culture. The experimental results show that the migratory phenotypes are preserved after several cell divisions. Also, the relative gene expression highlights some genes and gene groups owned to cellular migration. Cellule unique isolation cellulaire métastase cancer migration cellulaire séquençage photoblanchiment Single-cell cellular isolation metastasis cellular migration sequencing photobleaching
46	MACHINE LEARNING METHODS FOR SPECTRAL ANALYSIS Youlin Liu (11173365) 26 July 2021 (has links) Measurement science has seen fast growth of data in both volume and complexity in recent years, new algorithms and methodologies have been developed to aid the decision<br>making in measurement sciences, and this process is automated for the liberation of labor. In light of the adversarial approaches shown in digital image processing, Chapter 2 demonstrate how the same attack is possible with spectroscopic data. Chapter 3 takes the question presented in Chapter 2 and optimized the classifier through an iterative approach. The optimized LDA was cross-validated and compared with other standard chemometrics methods, the application was extended to bi-distribution mineral Raman data. Chapter 4 focused on a novel Artificial Neural Network structure design with diffusion measurements; the architecture was tested both with simulated dataset and experimental dataset. Chapter 5 presents the construction of a novel infrared hyperspectral microscope for complex chemical compound classification, with detailed discussion in the segmentation of the images and choice of a classifier to choose.<br> Cheminformatics GAN Raman spectra QCL adversarial attack data analysis hyperspectral imaging Spectral Analysis LDA PCA PLS-DA spectroscopy microscopy
47	Minghe Li thesis final.pdf Minghe Li (14184599) 29 November 2022 (has links) <p>The thesis consists of two main parts of nonlinear optical instrumentation development. </p> <p>Fluorescence-detected mid-infrared photothermal (F-PTIR) microscopy is demonstrated for sub-diffraction limited mid-infrared microspectroscopy of model systems and applied to probe phase transformations in amorphous solid dispersions. To overcome the diffraction limit in infrared imaging, a highly localized temperature-dependent photothermal effect is an attractive alternative indicator to infrared absorption. Photothermal atomic force microscopy infrared spectroscopy (AFM-IR) achieves nanometer resolution by monitoring heat caused expansion but only restricted on the surface. For 3D imaging, optically detected photothermal infrared (O-PTIR) combines an infrared laser with a visible probe source with to transduce photothermal refractive index changes (e.g., from changes in beam divergence or scattering). The sensitivity of O-PTIR is ultimately limited by the relatively weak dependence of refractive index with temperature, exhibiting changes of ~0.01% per oC. Fluorescence-detected photothermal mid-infrared (F-PTIR) spectroscopy (Fig. 1) is demonstrated herein to support 3D imaging with improved photothermal sensitivity. In F-FTIR, the sensitivity of fluorescence quantum efficiency to temperature change (~1-2% per oC) is used to transduce transient heat flux from localized IR absorption. The infrared spatial resolution of F-FTIR is defined by fluorescence microscopy and the thermal diffusivity of the sample instead of infrared wavelength. Initial F-PTIR proof of concept studies are described for microparticle assemblies of silica gel and polyethylene glycol, followed by applications of F-PTIR for analysis of localized composition within phase-separated domains induced by water vapor exposure of an amorphous solid dispersion (ritonavir in copovidone).</p> <p>Fluorescence recovery while photobleaching (FRWP) is demonstrated as a method for quantitative measurements of rapid diffusion mapping over the microsecond to millisecond time scale. Diffusion measurements are critical for molecular mobility assessment in cell biology, materials science and pharmacology. Fluorescence recovery after photobleaching (FRAP) is a well-known noninvasive optical microscopy method for measuring diffusion coefficients of macromolecules, such as proteins in cells and viscous solutions. However, conventional point-bleach FRAP is challenging to implement with multi-photon excitation and typically only supports diffusion analysis over millisecond time scales due to camera frame rate limitations. FRWP with patterned illumination addresses these limitations of FRAP by probing the fluorescence intensity changes while bleaching a comb pattern within a field of view (FoV). Fast-scanning of an ultrafast excitation beam distributes heat rapidly over multiple adjacent pixels, minimizing local heating effects that could complicate analogous diffusion measurements by point-bleach FRAP with multiphoton excitation. In FRWP, time-scales of the probed diffusion events are defined by a single line-pass time of a resonant scanning-mirror with a period of 125  s. In FRWP, the bleach pattern spans locations across the whole FoV, enabling diffusion mapping through image segmentation. More than a hundred bleaching and recovery events can be recorded during a single 10s measurement. Normal and anomalous diffusion of rhodamine-labeled bovine serum albumin (BSA) molecules was studied as a model system, with applications targeting rapid assessment of therapeutic macromolecule mobility within heterogeneous biological environments.</p> Analytical spectrometry photothermal IR spectroscopy second harmonic generation two photon flurescence
48	NONLINEAR OPTICAL METHODS AS APPLIED TO LARGE AND SMALL PHARMACEUTICAL MODALITIES Nita Takanti (9234683) 28 July 2022 (has links) <p>The overall time and cost for a drug to go from the drug discovery to the consumer market is significant, showing a need for improved drug testing and discovery methods. Work on nonlinear optical methods for both small active pharmaceutical ingredient drug formulation analysis and large biological therapeutic stability testing has been shown to improve testing times for formulation, stability and dissolution testing. Herein, we review the existing and conventional approaches to address stability testing that the pharmaceutical industry uses, and how leveraging nonlinear optical (NLO) methods can improve the current challenges. The specificity, sensitivity and low limit of detection of second harmonic generation is discussed in application to crystal formation in small-molecule active pharmaceutical ingredients. The nonlinear optical methods second harmonic generation and two-photon excited ultraviolet fluorescence are directly compared to ‘gold standard’ powder X-ray diffraction, which is commonly used for measuring crystal formation and growth of active pharmaceutical ingredients in amorphous solid dispersions. In addition, the existing FRAP method (with multiple limitations) is improved upon with the ability to perform recovered diffusion coefficient data analysis in the spatial Fourier domain. The collective results discussed in this thesis are just a small subset of the total breadth of investigations marrying the new challenges in the pharmaceutical industry with the new NLO tools tailored to meet them</p> second harmonic generation nonlinear optics active pharmaceutical ingredients powder x-ray diffraction monoclonal antibodies subcutaneous injection crystallization kinetics
49	Applications of optical-cavity-based spectroscopic techniques in the condensed phase Li, Jing January 2014 (has links) Cavity ring-down spectroscopy (CRDS) and cavity enhanced absorption spectroscopy (CEAS) are two well-established absorption spectroscopic techniques originally developed for gas-phase samples. Condensed-phase applications of these techniques still remain rare, complicated as they are by additional background losses induced by condensed-phase samples as well as the intracavity components in which the sample is constrained. This thesis is concerned with the development and application of optical-cavity-based techniques in the condensed phase. Polarization-dependent evanescent wave CRDS (EW-CRDS) has been used to study the molecular orientation at the solid/air and solid/liquid interfaces. An increase in average orientation angle with respect to the surface normal has been observed for both methylene blue and coumarin molecules as a function of coverage at the fused silica/air interface. An orientation-angle-dependent photobleaching of pyridin molecules at the fused silica/methanol interface have also been observed. EW-CRDS has also been used to monitor slow in situ photobleaching of thin dye films deposited on the prism surface. The photobleaching dynamics is interpreted as a combination of first- and second-order processes. A significant fraction of this thesis has been devoted to studying magnetic field effects (MFEs) on the kinetics of the radical pair (RP) reactions in solution, in an effort to understand the ability of animals to sense the geomagnetic field. Two novel optical-cavity-based techniques – broadband CEAS (BBCEAS) and CRDS have been developed for this purpose. BBCEAS uses a supercontinuum (SC) source as the cavity light source and a CCD camera as photodetector, enabling simultaneous acquisition of absorption spectrum across the whole visible region (400 – 800 nm). In CRDS, a tunable optical parametric oscillator has been used as the cavity light source. Combined with the switching of external magnetic field (SEMF) method, this technique allows the decay kinetics of the geminate RPs to be monitored, with nanosecond resolution. Both BBCEAS and CRDS provide sensitivity superior to single-pass transient absorption (TA), a technique traditionally used in the MFE studies. A series of photochemical systems have been studied by BBCEAS and CRDS, respectively, among which, the MFEs of drosophila melanogaster cryptochrome has been observed. Importantly, this is the first time an MFE has been observed in an animal cryptochrome, and provides key supporting evidence for the cryptochrome hypothesis of magnetoreception in animals. Besides the optical-cavity-based techniques, a novel fluorescence detection method of MFEs has also been demonstrated. This technique proved ultrahigh sensitivity when applicable. 543
50	Dynamique de chaînes de polymère greffés et glissement aux interfaces / Dynamics of grafted polymer chains and slip at solid-fluid interfaces Chennevière, Alexis 12 December 2014 (has links) Dans de nombreux cas, le développement de surfaces aux propriétés adhésives spécifiques fait appel à l’utilisation « d’interfaces décorées ». Ces interfaces sont composées d’un substrat solide sur lequel des chaînes de polymère sont plus ou moins bien ancrées. Ces chaînes se couplent mécaniquement au matériau environnant et contrôlent la transmission des contraintes de friction et d'adhésion aux interfaces. Ce couplage dépend en particulier de la pénétration des chaînes de surface dans la matrice et de leur dynamique. Dans cette thèse, les systèmes que nous avons étudiés sont constitués d’une couche de chaînes de polymère dont une extrémité est liée de manière covalente à un substrat solide. Ces brosses de polymère, constituent un système modèle pour des interfaces décorées. Notre objectif a été d’étudier la conformation et la dynamique de ces chaînes greffées lorsque ces dernières sont soumises à différents types de sollicitations afin de comprendre les mécanismes moléculaires régissant les propriétés d’adhésion et de friction de ce type d’interface. Dans un premier volet, nous avons étudié par réflectivité de neutrons la cinétique de cicatrisation d'une interface composée initialement de chaînes greffées recroquevillées sur un substrat et en contact avec un fondu. Lorsque le système est amené à une température supérieure à la température de transition vitreuse, les chaînes de polymère retrouvent une mobilité non nulle permettant ainsi la pénétration des chaînes greffées dans le fondu de polymère. La réflectivité de neutrons nous a permis d'une part de sonder à l'échelle moléculaire la cinétique de cicatrisation de ce type d’interface et d'autre part de la quantifier. L'influence des paramètres moléculaires sur cette cinétique de cicatrisation a pu être observée, ce qui nous a permis de proposer un modèle en loi d'échelle permettant d'apporter une interprétation physique au phénomène étudié. La deuxième partie de ce travail de thèse a consisté en l'élaboration d'un dispositif expérimental permettant de cisailler un système brosse/fondu au-dessus de la température de la température transition vitreuse et de geler la conformation des chaînes greffées dans leur configuration cisaillée. L'inversion des spectres de réflectivité neutrons associés a permis de mettre en évidence l'influence du cisaillement sur le degré d'interpénétration entre la brosse et le fondu qui régit la transmission des contraintes de friction sur ce type d'interface. De plus, nous avons pu mesurer la cinétique de relaxation de chaînes greffées, cisaillées au préalable, et la comparer aux expériences d’interdigitation simple. Cette comparaison a permis de divulguer l’importance du type de sollicitation sur la cinétique de relaxation d’une interface brosse / fondu.Nous avons également observé que la cinétique de relaxation et la conformation de chaînes greffées peuvent être altérées lorsque ces dernières sont confinées dans un film d'épaisseur comparable au rayon de giration des chaînes. Une étude systématique par réflectivité de neutrons a permis de mettre en évidence une accélération de la cinétique de relaxation du système en dessous d'une épaisseur critique qui pourrait être interprétée en termes de déplacement de la température de transition vitreuse. Dans un deuxième temps, nous avons étudié le glissement de solutions de polymères sur une surface greffée. La fraction volumique en chaînes libres dans la solution est un paramètre supplémentaire aux trois cas précédents qui contrôle ici le degré d'interpénétration entre chaînes libres et chaînes greffées. Une première approche théorique a permis de dissocier différents régimes de glissements à la paroi en fonction de fraction volumique. Nous avons entrepris une première série d'expériences de vélocimétrie laser après photolyse afin de mesurer le glissement à la paroi de solutions de polymère et de confronter les résultats expérimentaux avec notre approche théorique. / In many cases, the development of surfaces with specific adhesive properties involves the use of "decorated interfaces." These interfaces consist of a solid substrate on which polymer chains are more or less well anchored. These chains are mechanically coupled to the surrounding material and control the transmission of friction and adhesion stresses at the interfaces. This coupling depends particularly on the penetration of the surface chains within the matrix and on their own dynamics. In this thesis, the systems we investigated are composed of a layer of polymer chains whose end is covalently linked to a solid substrate. These, so called, polymer brushes, provide a model system for decorated interfaces. Our objective was to study the conformation and dynamics of these grafted chains when they are subjected to different types of stress in order to understand the molecular mechanisms governing the adhesion and friction properties of this type of interface.In the first part, we investigated the healing kinetics of an interface composed initially of grafted chains collapsed on a substrate and in contact with a molten by using neutron reflectivity. When the system is brought above the glass transition temperature, the polymer chains mobility is high enough to allow the penetration of the grafted chains within the polymer melt. Neutrons reflectivity allowed us to probe at the molecular scale and to quantify the healing kinetics of this type of interface. The influence of molecular parameters on this healing kinetics was observed, which allowed us to propose a scaling law model to give a physical interpretation to the phenomenon studied.The second part of this thesis consisted in the development of an experimental setup which is able to shear a brush / melt interface above the glass transition temperature and to freeze the conformation of chains grafted in their sheared conformation. The inversion of the associated neutron reflectivity spectra made it possible to demonstrate the influence of shear on the degree of interpenetration between the brush and the melt which governs the transmission of stresses. In addition, we measured the kinetics of relaxation of grafted chains previously sheared and we compared it to the interdigitation experiments. This comparison highlighted the influence of the kind of solicitation on the relaxation kinetics of a brush/melt interface.We also observed that the relaxation kinetics and the conformation of the grafted chains may be altered when they are confined in a film which thickness is comparable to the radius of gyration of the chains. A systematic study using neutron reflectivity was conducted and highlighted an acceleration of the relaxation kinetics of the system below a critical thickness which could be interpreted in terms of a shift in the glass transition temperature.Secondly, we studied the slip of polymer solutions onto a grafted surface. The volume fraction of free chains in solution is an additional parameter which controls the degree of interpenetration between free chains and grafted chains. A first theoretical approach showed that different slip regimes can occur as a function of volume fraction. We have undertaken a first series of experiments using laser velocimetry after photobleaching to measure the surface velocity of flowing polymer solutions and to compare the experimental results to our theoretical approach. Polymères Adhésion Réflectivité Neutrons Glissement Matière molle Films minces Transition vitreuse Vélocimétrie Polymers Adhesion Reflectivity Neutrons Slip Soft matter Thin films Glass transition Velocimetry

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