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1	Création d'une banque de scFv-phages ciblant des protéines hydrophiles ou membranaires / Creation of a new scFv-phage library targeting hydrophilic or membrane proteins Muller, Benjamin 15 December 2014 (has links) Actuellement, 60% des médicaments sur le marché ont pour cible des protéines membranaires. Toutefois, l'étude de ces protéines membranaires reste un challenge de par leur structure particulière (domaines transmembranaires hydrophobes et domaines extra- et intra-cellulaires hydrophiles), mais également par leur faible expression sur les cellules.L'entreprise Ciloa, dans laquelle j'ai effectué ma thèse, a développé une technologie brevetée, qui permet d'exprimer à la surface des exosomes, des vésicules membranaires de tailles comprises entre 30 et 100nm, des protéines membranaires natives, grâce à un peptide d'adressage, le DCTM. Cette technologie possède de nombreux domaines d'applications, comme le criblage de médicaments, le développement de vaccins ou encore le développement d'anticorps monoclonaux.L'objectif de ma thèse a été, dans un premier temps, de mettre en place l'outil exosomes recombinants grâce à la technologie de Ciloa et dans un deuxième temps, d'utiliser ces outils pour le développement d'anticorps, grâce aux exosomes recombinants.Ainsi, j'ai d'abord mis au point différentes techniques de caractérisation des exosomes recombinants (ELISA), et également participé à la mise en place de différents protocoles de production et de purification, en fonction leur utilisation. Une fois ces outils optimisés, j'ai pu les utiliser pour le développement d'anticorps. J'ai testé en parallèle deux méthodes de production d'anticorps, une méthode classique, l'hybridation lymphocytaire après immunisation de souris BALB/c, et une méthode plus récente, le criblage d'une banque de scFvs par phage display.L'hybridation lymphocytaire a permis la production d'hybridomes, dont les anticorps ont été criblés sur exosomes, par ELISA. Dans le cadre du criblage par phage display, j'ai participé au développement d'une banque de scFvs, basée sur le modèle du 13R4, dont nous avons modifié les longueurs de boucles des différents CDRs, notamment le CDRH3, afin de cibler les épitopes faiblement accessibles des protéines membranaires. Les sélections de scFvs ont été effectuées sur exosomes recombinants, exprimant des protéines membranaires. / Nowadays, more than 60% of marketed drugs target membrane proteins. However, their study still represents a challenge, essentially due to their particular 3D-structure (hydrophobic transmembrane domains and hydrophilic extra- and intra-cellular domains), but also to their low expression level in cells.Ciloa, the start-up company in which I realized my PhD, has developed a patented technology that enables to express native membrane proteins on exosomes, membrane vesicles of 30 to 100nm, using a pilot peptide called DCTM (for Cytosolic Domain of TransMembrane). This technology displays a lot of different applications, in different domains such as drug screening, vaccines development or monoclonal antibodies (mAbs) development.The purpose of my PhD research was, first, to set up the recombinant exosomal tool using Ciloa's innovative technology, and then to use this tool to develop monoclonal antibodies.Thus, at the beginning of my PhD, I set up exosomal characterization technics, such as ELISA, and I also took part in the setup of several production and purification protocols, depending of the use of exosomes. Once these tools had been optimized, I was able to use them to develop mAbs. I tested two methods, one classical, the generation of hybridoma after Balb/c mice immunizations, and a more recent technology, the screening of scFvs library by phage display.Therefore, I obtained hybridoma and was able to screen the derived antibodies by ELISA on exosomes. Concerning the phage display technology, I took part in the development of a new scFvs library, based on the 13R4 scaffold, of which we changed the CDRs lengths, mostly the CDRH3, in order to target epitopes with low accessibility, such as the one of membrane proteins. The library screening was realized on recombinant exosomes. Anticorps monoclonaux Exosomes Phage display Hybridomes Monoclonal antibodies Exosomes Phage display Hybridoma 615
2	Identification et caractérisation d'une protéine de Streptococcus pneumoniae potentiellement impliquée dans le mécanisme de l'adhérence / Sylvain, Marie-Josée. January 1997 (has links) Thèse (M.Sc.) -- Université Laval, 1997. / Bibliogr.: f. 104-125. Publié aussi en version électronique.
3	Modélisation et simulation de l'atmosphère d'une enceinte membranaire pour des tests de toxicité / Modeling and simulation of the atmosphere of a membrane enclosure for toxicity tests Stoian, Alina 02 April 2012 (has links) Un problème fondamental pendant l'évaluation in vitro de la toxicité de composés organiques volatils (COVs) est le manque de connaissance de l'évolution de la concentration des COVs à laquelle les systèmes vivants sont exposés au cours des études expérimentales. Ce travail présente un nouveau dispositif expérimental conçu pour étudier l'exposition des systèmes vivants aux COVs. Le dispositif est formé de deux compartiments séparés par une membrane hydrophobe poreuse et permet des durées relativement longues de manipulations sans restreindre la respiration cellulaire. Une modélisation théorique qui couple la conservation de masse et du moment entre les différentes phases et la respiration des cellules hybridomes (ATCC CRL-1606) au sein du dispositif a été développée. Le modèle permet de prédire l'évolution de la concentration des COVs, de l'oxygène et du dioxyde de carbone dans le dispositif. Les résultats simulés pour le transfert des COVs ont revélé une bonne concordance avec les résultats expérimentaux et ont montré que le type de membrane et son diamètre, le coefficient de partage des COVs et la hauteur de la phase liquide ont une influence significative sur l'évolution de la concentration de ceux-ci dans la phase liquide. Néanmoins la disponibilité de l'oxygène au niveau des cellules dépend principalement de la densité cellulaire initiale, de la vitesse spécifique de consommation de ce gaz et de la hauteur du liquide alors que les paramètres liés à la membrane ont une influence sur le contrôle du pH. / A major problem during in vitro evaluation of the toxicity of volatile organic compounds (VOC) is the lack of knowledge of the evolution of the concentration of such compounds during the course of experimental studies with living systems. This work presents the design of a novel experimental device for the study of cell culture exposure to VOCs. The device is made of two compartments separated by a porous hydrophobic membrane and allows relatively long durations of handling without restricting cellular breathing. A theoretical modeling which couples mass and moment conservation between the different phases inside the device with the breathing kinetics of hybridoma cells (ATCC CRL-1606) was developed. The model allows predicting the evolution of the concentration of the VOCs, the oxygen and the carbon dioxide inside the device. The simulations of the mass transfer of the VOCs simulated presented a good agreement with experiments and showed that the type of membrane and its diameter, the VOCs partition coefficient and the height of the liquid phase have a significant influence on the evolution of their concentration in the liquid phase. Nevertheless, the availability of oxygen for the cells depends mainly on the initial cellular density, the specific kinetics of consumption of this gas and on the height of the liquid phase, whereas the parameters related to membrane have an influence on the control of the pH. Dispositif pour tests in vitro Cov Modélisation théorique Respiration cellulaire Cellules hybridomes (ATCC CRL-1606) In vitro tests device Voc Theoretical modeling Cells breathing Hybridoma cells (ATCC CRL-1606)
4	Macroscopic modelling of hybridoma cell fed-batch cultures with overflow metabolism: model-based optimization and state estimation Amribt, Zakaria 23 June 2014 (has links) Monoclonal antibodies (MAbs) have an expanding market for use in diagnostic and therapeutic applications. Industrial production of these biopharmaceuticals is usually achieved based on fed-batch cultures of mammalian cells in bioreactors (Chinese hamster ovary (CHO) and Hybridoma cells), which can express different kinds of recombinant proteins. In order to reach high cell densities in these bioreactors, it is necessary to carry out an optimization of their production processes. Hence, macroscopic model equations must be developed to describe cell growth, nutrient consumption and product generation. These models will be very useful for designing the bioprocess, for developing robust controllers and for optimizing its productivity.<p>This thesis presents a new kinetic model of hybridoma cell metabolism in fed batch culture and typical illustration of a systematic methodology for mathematical modelling, parameter estimation and model-based optimization and state estimation of bioprocesses. <p>In the first part, a macroscopic model that takes into account phenomena of overflow metabolism within glycolysis and glutaminolysis is proposed to simulate hybridoma HB-58 cell cultures. The model of central carbon metabolism is reduced to a set of macroscopic reactions. The macroscopic model describes three metabolism states: respiratory metabolism, overflow metabolism and critical metabolism. The model parameters and confidence intervals are obtained via a nonlinear least squares identification. It is validated with experimental data of fed-batch hybridoma cultures and successfully predicts the dynamics of cell growth and death, substrate consumption (glutamine and glucose) and metabolites production (lactate and ammonia). Based on a sensitivity analysis of the model outputs with respect to the parameters, a model reduction is proposed. <p>In the next step, the effort is directed to the maximization of biomass productivity in fed-batch cultures of hybridoma cells based on the overflow metabolism model. Optimal feeding rate, on the one hand, for a single feed stream containing both glucose and glutamine and, on the other hand, for two separate feed streams of glucose and glutamine are determined using a Nelder-Mead simplex optimization algorithm. Two different objective functions (performance criteria) are considered for optimization; the first criterion to be maximized is the biomass productivity obtained at the end of the fed-batch culture, the second criterion to be minimized is the difference between global substrate consumption and the maximum respiratory capacity.<p>The optimal multi exponential feed rate trajectory improves the biomass productivity by 10% as compared to the optimal single exponential feed rate. Moreover, this result is validated by the one obtained with the analytical approach in which glucose and glutamine are fed to the culture so as to control the hybridoma cells at the critical metabolism state, which allows maximizing the biomass productivity. The robustness analysis of optimal feeding profiles obtained with different optimization strategies is considered, first, with respect to parameter uncertainties and, finally, with respect to model structure errors.<p>Finally, the overflow metabolism model is used to develop an extended Kalman filter for online estimation of glucose and glutamine in hybridoma cell fed-batch cultures based on the considered available measurements (biomasses (on-line), lactate and ammonia (on-line or off-line)). The observability conditions are examined, and the performances are analysed with simulations of hybridoma cell fed-batch cultures. Glutamine estimation sensitivity is enforced by minimizing a cost function combining a usual least-squares criterion with a state estimation sensitivity criterion. <p> / Doctorat en Sciences de l'ingénieur / info:eu-repo/semantics/nonPublished Contrôle des matériaux Cell culture Hybridomas Cellules -- Culture Hybridomes State estimation Bioprocess optimization Overflow metabolism Macroscopic modelling Mammalian cell cultures Hybridoma cultures

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