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Rôle de la cytoarchitecture dans la signalisation énergétique du cœur de souris / Role of cell architecture in energetic signalling of mouse heartPiquereau, Jérôme 07 January 2011 (has links)
La cellule cardiaque requiert un apport énergétique conséquent qui exige une production et un transfert énergétiques efficaces. Si la production de l’énergie dépend essentiellement des propriétés intrinsèques des mitochondries, il semblerait que l’efficacité du transfert d’énergie du site de production vers les sites consommateurs (ATPases) pourrait être liée à l’architecture spécifique du cardiomyocyte qui conduit à une organisation spatiale singulière des structures internes (mitochondries, réticulum sarcoplasmique, myofilaments). Pour comprendre ce qui lie la cytoarchitecture, la compartimentation cellulaire et la fonction contractile, il a été entrepris d’étudier l’architecture cellulaire et la signalisation énergétique de cardiomyocytes au cours du processus de maturation de la cytoarchitecture et dans un modèle présentant une désorganisation des structures intracellulaires. La première partie de ce travail, réalisée durant le développement postnatal de la souris, a permis de démontré qu’il existe une synchronisation parfaite entre la mise en place de la cytoarchitecture et la maturation fonctionnelle du transfert d’énergie par canalisation directe des nucléotides adényliques entre les mitochondries et les ATPases. Si cette étude apporte un élément qui tendrait à démontrer l’implication de l’architecture cellulaire dans l’efficacité des transferts d’énergie, elle a également mis en avant la maturation très précoce de l’énergétique cellulaire. La mitochondrie faisant partie intégrante de cette architecture et étant modelée par des mécanismes de fusion et de fission, la deuxième étape de ce travail de thèse a consisté à étudier l’implication de la morphologie mitochondriale dans l’énergétique du cardiomyocyte. Il a ainsi été montré que, chez la souris, la diminution d’expression de la protéine OPA1, impliquée dans la fusion mitochondriale, conduit à des perturbations de la morphologie mitochondriale qui n’affectent pas la fonction intrinsèque mitochondriale mais qui altèrent le système de canalisation directe entre les mitochondries et les ATPases des myofilaments. De manière générale, ces résultats démontrent clairement une dépendance des transferts d’énergie à l’architecture cellulaire spécifique de la cellule musculaire cardiaque. / The cardiac cell function requires a large amount of energy and therefore needs a high efficiency of energetic production and energetic transfer. While the energy production depends on the intrinsic properties of the mitochondria, it appears that the efficiency of energetic transfers from the main producers (mitochondria) to consumers (ATPases) could be related to the specific architecture of the cardiomyocyte, which ensures a unique spatial organization of internal structures (mitochondria, sarcoplasmic reticulum, myofilaments). In order to reveal the role of mitochondrial network organization in cardiac energy metabolism, we studied the cellular architecture and the energetic signalling of cardiomyocytes in the process of maturation of the cytoarchitecture and in a model which exhibits a perturbation of the mitochondrial dynamics. The first part of this work, which was performed during postnatal development of the mouse, showed the perfect synchronisation between the establishment of the cytoarchitecture and the maturation of the transfer of energy by direct channelling of adenine nucleotides between mitochondria and ATPases. While this study provides an element which would demonstrate the involvement of cellular architecture in the efficiency of energy transfer, it also highlighted the very early maturation of the energetic system of the cell. Knowing that the mitochondria are an integral part of the cell architecture and that the mitochondrial network is controlled by fusion and fission mechanisms, the second step of this work consisted in investigating the involvement of mitochondrial dynamics in cardiomyocyte energetics. Our work has shown that a decrease in expression of OPA1, a protein responsible for mitochondrial fusion, leads to disruption of mitochondrial morphology which does not affect intrinsic mitochondrial function but affects the direct channelling of ATP and ADP between mitochondria and ATPases of the myofilaments. Overall, these results clearly demonstrate that energy transfer in cardiomyocytes strictly depends on specific cellular architecture.
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Chemical modifications and passivation approaches in metal halide perovskite solar cellsAbdi Jalebi, Mojtaba January 2018 (has links)
This dissertation describes our study on different physical properties of passivated and chemically modified hybrid metal halide perovskite materials and development of highly efficient charge transport layers for perovskite solar cells. We first developed an efficient electron transport layer via modification of titanium dioxide nanostructure followed by a unique chemical treatment in order to have clean interface with fast electron injection form the absorber layer in the perovskite solar cells. We then explored monovalent cation doping of lead halide perovskites using sodium, copper and silver with similar ionic radii to lead to enhance structural and optoelectronic properties leading to higher photovoltaic performance of the resulting perovskite solar cells. We also performed thorough experimental characterizations together with modeling to further understand the chemical distribution and local structure of perovskite films upon monovalent cation doping. Then, we demonstrate a novel passivation approach in alloyed perovskite films to inhibit the ion segregation and parasitic non-radiative losses, which are key barriers against the continuous bandgap tunability and potential for high-performance of metal halide perovskites in device applications, by decorating the surfaces and grain boundaries with potassium halides. This leads to luminescence quantum yields approaching unity while maintaining high charge mobilities along with the inhibition of transient photo-induced ion migration processes even in mixed halide perovskites that otherwise show bandgap instabilities. We demonstrate a wide range of bandgaps stabilized against photo-induced ion migration, leading to solar cell power conversion efficiencies of 21.6% for a 1.56 eV absorber and 18.3% for a 1.78 eV absorber ideally suited for tandem solar cells. We then systematically compare the optoelectronic properties and moisture stability of the two developed passivation routes for alloyed perovskites with rubidium and potassium where the latter passivation route showed higher stability and loading capacity leading to achieve substantially higher photoluminescence quantum yield. Finally, we explored the possibility of singlet exciton fission between low bandgap perovskites and tetracene as the triplet sensitizer finding no significant energy transfer between the two. We then used tetracene as an efficient dopant-free hole transport layer providing clean interfaces with perovskite layer leading to high photoluminescence yield (e.g. ~18%). To enhance the poor ohmic contact between tetracene and the metal electrode, we added capping layer of a second hole transport layer which is extrinsically doped leading to 21.5% power conversion efficiency for the subsequent solar cells and stabilised power output over 550 hours continuous illumination.
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