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Intermediate filaments in mammalian cell motility
Čermáková, Kateřina ; Libusová, Lenka (advisor) ; Pelantová, Markéta (referee)
Cell migration is crucial for the formation and maintenance of a multicellular mammalian organism, contributing to important processes such as embryonic development, tissue renewal, and immune surveillance. It is a complex phenomenon involving a plethora of processes, including relevant signalization. An impairment of those processes could be projected into innumerable pathological states, from wound healing disruption to tumour metastasis and invasiveness, thus the interest of many researchers has turned toward migration. The migration of mammalian cells is dependent on a cytoskeleton, which is being considerably rearranged in motile cells. This thesis aims to summarise the role of intermediated filaments in cell motility - the less understood cytoskeletal network in this context. Cytoplasmic, as well as nuclear intermediate filaments, due to their unique mechanical properties, affect cell mechanics. They protect against physical stresses (as cells squeeze through confined pores in a complex intercellular microenvironment) and modulate and direct actomyosin-generated forces, which are the main driving force of migration. In addition, they contribute to important migration- involved steps, such as cell polarisation, cell adhesion to surrounding surfaces, cohesion in collective migration, and...
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Thin films of plasma polymers as stable supports for biomedical applications
Gordeev, Ivan ; Shukurov, Andrey (advisor) ; Novák, Rudolf (referee) ; Pavlík, Jaroslav (referee)
Title: Thin films of plasma polymers as stable supports for biomedical applications Author: Ivan Gordeev Institute: Charles University in Prague, Department of Macromolecular Physics Supervisor of the doctoral thesis: Doc. Ing. Andrey Shukurov, Ph.D, Charles University in Prague, Department of Macromolecular Physics. Abstract: Plasma polymers have been widely considered for use as bio-active coatings. In biomedicine, the surfaces that withstand accumulation of biofilms are of particular importance. This thesis is focused on development of new plasma-based methods for deposition of bio-resistant (non-fouling) plasma polymers. Poly(ethylene oxide) was the subject material. R.f. magnetron sputtering, plasma-assisted thermal vapour deposition and amplitude modulated atmospheric pressure surface dielectric barrier discharge were the methods adapted to fabricate thin films with tunable chemical composition, cross-link density and biological response. A new insight was gained into the processes of plasma polymerization as well as into composition/structure relationship and its effect on biological properties of resultant films. Keywords: plasma polymerization, PEO, 'non-fouling' properties, protein adsorption, cell adhesion
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