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Žádný přesný výsledek pro Martinovou,, Lenku nebyl nalezen, zkusme místo něj použít Martinovou Lenku ...
Národní úložiště šedé literatury Nalezeno 2 záznamů.  Hledání trvalo 0.01 vteřin. 
Advanced preparation of inorganic (ceramic) particles and nanostructures
 Šťastná, Eva ; Martinovou,, Lenku (oponent) ; Vojtová, Lucy (oponent) ; Částková, Klára (vedoucí práce)
An electrospinning process was used for bioactive nanofibrous structures preparation. Neat polycaprolactone nanofibres and polycaprolactone nanofibres containing hydroxyapatite nanoparticles were successfully prepared via electrospinning and characterized using scanning electron microscopy. Mechanical properties of the nanofibres were analyzed using uniaxial tensile strength test. Results of the testing showed strong influence of the nanofibres direction alignment and nanoparticles presence on the mechanical properties of the prepared structures. The direction alignment contributed to higher elastic modulus and failure stress regardless the presence of the hydroxyapatite nanoparticles in the structure. However, the direction alignment considerably reduced failure strain of the structure. An interesting phenomenon occurred by the composite nanofibres – the influence of the hydroxyapatite particles was more distinct by the random fibres (they worsened failure strain and failure stress of the random composite fibres) but the hydroxyapatite particles did not have such strong effect on the parallelly aligned fibres. The samples were then modified by surface low-temperature plasma treatment to improve biological properties of the nanofibres. Change of the nanofibres surface characteristics was examined by contact angle measurement by sessile drop method and by XPS spectroscopy. The contact angle measurement showed that the plasma treatment considerably increased structures hydrophilicity – was unmeasurable. The XPS analysis explained the effect of the plasma treatment on microscopical scale – the plasma treatment had affected only polymer constituent of the treated structure, the hydroxyapatite nanoparticles remained intact. Selected prepared structures were biologically tested. Test in simulated body fluid proved high bioactivity of the polycaprolactone/hydroxyapatite composite nanofibres through precipitation of calcium phosphates phases on the composite structures. Following in-vitro tests using living cell cultures (ISO 10993-5 and WST-8 test) proved beneficial influence of the hydroxyapatite in the structure and of the surface plasma treatment when bioactivity of the plasma treated composite structures increased 1.5 times compared to the neat as-spun polycaprolactone fibres.
Úplný záznam
Advanced preparation of inorganic (ceramic) particles and nanostructures
 Šťastná, Eva ; Martinovou,, Lenku (oponent) ; Vojtová, Lucy (oponent) ; Částková, Klára (vedoucí práce)
An electrospinning process was used for bioactive nanofibrous structures preparation. Neat polycaprolactone nanofibres and polycaprolactone nanofibres containing hydroxyapatite nanoparticles were successfully prepared via electrospinning and characterized using scanning electron microscopy. Mechanical properties of the nanofibres were analyzed using uniaxial tensile strength test. Results of the testing showed strong influence of the nanofibres direction alignment and nanoparticles presence on the mechanical properties of the prepared structures. The direction alignment contributed to higher elastic modulus and failure stress regardless the presence of the hydroxyapatite nanoparticles in the structure. However, the direction alignment considerably reduced failure strain of the structure. An interesting phenomenon occurred by the composite nanofibres – the influence of the hydroxyapatite particles was more distinct by the random fibres (they worsened failure strain and failure stress of the random composite fibres) but the hydroxyapatite particles did not have such strong effect on the parallelly aligned fibres. The samples were then modified by surface low-temperature plasma treatment to improve biological properties of the nanofibres. Change of the nanofibres surface characteristics was examined by contact angle measurement by sessile drop method and by XPS spectroscopy. The contact angle measurement showed that the plasma treatment considerably increased structures hydrophilicity – was unmeasurable. The XPS analysis explained the effect of the plasma treatment on microscopical scale – the plasma treatment had affected only polymer constituent of the treated structure, the hydroxyapatite nanoparticles remained intact. Selected prepared structures were biologically tested. Test in simulated body fluid proved high bioactivity of the polycaprolactone/hydroxyapatite composite nanofibres through precipitation of calcium phosphates phases on the composite structures. Following in-vitro tests using living cell cultures (ISO 10993-5 and WST-8 test) proved beneficial influence of the hydroxyapatite in the structure and of the surface plasma treatment when bioactivity of the plasma treated composite structures increased 1.5 times compared to the neat as-spun polycaprolactone fibres.
Úplný záznam

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