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In vitro testing of carrier system based on nanofibres for vitiligo treatment
Kodedová, Barbora ; Amler, Evžen (advisor) ; Kuželová Košťáková, Eva (referee)
Vitiligo is a skin disease with 2 % prevalence in a worldwide population. It is characterised by loss or decrease in activity of epidermal melanocytes, which lead to skin and hair depigmentation. It has negative impact on psyche, social relationships of patients and reduces the protection of the organism against UV radiation. One of the treatment methods is autologous transplantation of melanocytes or suspension of melanocytes with keratinocytes. Use of the biocompatible membrane, which allows the cultivation of these cells with resulting transplantation on the depigmented lesion, could improve treatment and make it more efficient. The main goal of this work was to create the biocompatible membrane from nanofiber layers of polyvinylalcohol (PVA) which can stand as a carrier for cell transplants in vitiligo therapy. PVA scaffolds were prepared by electrostatic spinning and later on modified by cold methane plasma (CH4) for lowering their hydrofility. Samples of modified nanofiber carriers were analysed according to their physical and chemical characteristics (visualization fiber morphology by SEM, XPS and surface Zeta potential analysis and contact angle). Consequently, adhesion, proliferation and metabolic activity of cultivating mice cell lines of melanocytes (Melan-a) and keratinocytes (XB2) were examined...
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Plasma modification of functionalized PVA nanofibers for the enhancement of mesenchymal stem cell adhesion, viability and proliferation.
Bezděková, Dagmar ; Amler, Evžen (advisor) ; Gášková, Dana (referee)
Electrospinning is widely used technique to produce nanoscale constructs for tissue engineering. This technique can be used to spin wide range of polymers. One of them is polyvinyl alcohol (PVA), which has very good properties for use in this field. PVA is nontoxic, has good mechanical strength and it's degradable and biocompatible. Electrospun PVA nanofibers have limitations because of their -OH side groups. These groups cause solubility of PVA in water. The solubility can be adjusted with crosslinking techniques, but PVA still remains very hydrophilic, which is causing low adhesion of cells. In recent research we decided to reduce the hydrophilicity of PVA using plasma modification. Polymer modification with cold plasma is an economic and quite simple process to change the surface chemistry without side effects that come with conventional chemical treatment. With radical, formed by discharge, we have deposited hydrocarbons on the PVA surface and we rapidly increased hydrophobicity of the polymer surface. The change of surface chemistry has only a little effect on the fiber morphology. The increase of hydrophobicity allowed better adhesion of mesenchymal stem cells on plasma modified PVA as compared to non-modified PVA and a huge change in cell morphology was observed. These changes suggest that we...
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Plasma modification of materials for medical purposes
MATĚJÍČEK, Jan
This diploma thesis deals with the ongoing research under the auspices of the Department of Applied Physics and Technics Faculty of Education, University of South Bohemia in České Budějovice, in which the author of the work was actively participated. The thesis is divided into theoretical and experimental part. The theoretical part contains information from natural polymers, especially cellulose, plasma technology and infrared spectrometry. The subject of the experimental part of the thesis is research that deals with the functionalization of cellulose using a microwave plasma discharge on the apparatus CX-22. In the present research was also conducted to process optimization of functionalization with the liquid precursor hexamethyldisiloxane (HMDSO).
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Plasma modification of powder materials
ČERNÝ, Pavel
Thesis is focused on plasma modification of materials. The work has the character of a search of available literature, especially the papers presented in impacted journals. The aim is to provide a broader overview of the subject. The first section describes the most commonly modified powdered materials. The second part is focused on the plasma modification, the reasons for its use, capabilities and benefits respectively and disadvantages of these processes. The following sections are devoted to plasma discharges, plasma reactors, aspects of plasma modification and companies engaged in production, or modification of powders. Each chapter is intended to provide an overview of the modified powder materials, processes within the plasma discharges, construction and use of plasma reactors, plasma modification of aspects and the market situation in the context of powdered materials and companies dealing with the plasma modification.
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