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Microscopic origin of the rheological and surface properties of embryonic cell aggregates / Origine microscopique des propriétés rhéologiques et de surface des agrégats de cellules embryonnairesStirbat, Tomita Vasilica 28 September 2012 (has links)
Ces travaux de thèse portent sur l'étude expérimentale des propriétés physiques et de la biomécanique des agrégats cellulaires embryonnaires. Le but de cette thèse était d'une part de mieux comprendre l'origine biologique de la viscosité et de la tension de surface tissulaire, d'autre part d'étudier quantitativement en détail l'élasticité cellulaire par des nouvelles mesures de rhéologie en cisaillement. Un premier chapitre concerne les mesures de tension de surface tissulaire par la méthode de compression et de viscosité tissulaire par analyse de la cinétique de fusion de deux agrégats en faisant varier comme paramètre principal la contractilité cellulaire que certains suspectent comme étant la principale origine biologique de ces paramètres. Nous utilisons le formalisme du DITH (Haris, 1976: Differential Interfacial Tension Hypothesis) pour interpréter les données. Le deuxième chapitre concerne les mesures rhéologiques en cisaillement à l'aide d'un rhéomètre commercial plan-plan sur plusieurs centaines ou milliers d'agrégats cisaillés ensembles. Nous montrons que les cellules deviennent moins rigides pour une déformation minimale d'environ 4%, mais sur l'échelle de l'heure les cellules sont capables de se rigidifier à nouveau. Ces expériences sont analysées à l'aide d'un modèle de ressorts qui cassent sous contrainte puis se ressoudent à contrainte nulle / This thesis focuses on the experimental study of physical properties and biomechanics of embryonic cell aggregates. The aim of this thesis was on one hand to better understand the biological origin of tissue viscosity and tissue surface tension, and on the other hand to study quantitatively in detail cell elasticity by means of new rheological measurements in shear. A first chapter deals with measurements of tissue surface tension by tissue compression method and tissue viscosity by analysis of the fusion kinetics of two aggregates. We vary key parameters such as cell contractility that some people suspect to be the main biological origin of these parameters. We use the formalism of DITH (Haris, 1976: Differential Interfacial Tension Hypothesis) to interpret the data. The second chapter deals with rheological measurements in shear using a commercial plate-plate rheometer over several hundred of aggregates. We showed that cells become softer after a minimal deformation of 4% is reached, and can harden again on the timescale of hour. These experiences are analyzed using a model of springs that break under stress and then reattach at zero strain
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Variační metody v termomechanice kontinua pevné fáze / Variational Methods in Thermomechanics of SolidsPelech, Petr January 2020 (has links)
The thesis is devoted to study of continuum mechanics and thermodynamics and the related mathematical analysis. It consists of four self-contained chapters dealing with different aspects. The first chapter focuses on peridynamics, a non-local theory of continuum mechanics, and its relation to conventional local theory of Cauchy-Green elasticity. Similar compar- isons has been used for proving consistency and for determining some of the material coefficients in peridynamics, provided the material parameters in the local theory are known. In this chapter the formula for the non-local force-flux is computed in terms of the peridynamic interaction, relating the fundamental concepts of these two theories and establishing hence a new connection, not present in the previous works. The second and third chapters are both devoted to Rate-Independent Systems (RIS) and their applications to continuum mechanics. RIS represents a suitable approximation when the internal, viscous, and thermal effects can be neglected. RIS has been proven to be useful in modeling hysteresis, phase transitions in solids, elastoplasticity, damage, or fracture in both small and large strain regimes. In the second chapter the existence of solutions to an evolutionary rate-independ- ent model of Shape Memory Alloys (SMAs) is proven. The model...
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