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Smart biomaterials for connective tissues regeneration
Hefka Blahnová, Veronika ; Filová, Eva (advisor) ; Maxová, Hana (referee) ; Motlík, Jan (referee)
Connective tissues are characterized by significant volume of extracellular matrix. Their main role is to provide a mechanical support and protection to other body organs. This thesis is focused on regeneration of bone, cartilage and osteochondral defect. In the experimental part we observed viability and differentiation of human mesenchymal stem cells. In vitro we evaluated the potential of PCL scaffold with addition of growth factors, bone xenograft with biomimetic peptides, collagen I composite with bioceramics and a titanium alloy with nanostructured surface. During following in vivo study, we implanted a cell-free scaffold made of PCL, calcium phosphate and IGF-1, bFGF, TGFβ1 and BMP-2 to osteochondral defect. Unfortunately, addition of growth factors resulted in pathological inflammatory process despite clear beneficial effect in vitro. Likewise, the biomimetic peptide sequences promoted osteogenic differentiation of human mesenchymal stem cells. Addition of certain bioceramics influenced the scaffold morphology in the manner of pore size. However, we did not observe any effect of the surface characteristics on cell behavior. The cells were influenced rather by certain material. On the other hand, surface modification of titanium scaffold by anodic oxidation revealed that the most suitable...
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Genetic regulation of the cranial cartilage and bone development
Burianová, Andrea ; Machoň, Ondřej (advisor) ; Kaucká, Markéta (referee)
The skull development is an elaborate sequence of cellular processes, featuring two distinct tissue lineages, a unique transient pluripotent population of neural crest cells and mesodermal cells. Several differences in molecular mechanisms operating during chondrogenesis and skeletogenesis have been demonstrated in cranial bones originating from these different cell lineages. The bones comprising the cranial skeleton are formed through both intramembranous and endochondral ossification, regardless of the origin. The cellular processes involved in the formation of cranial skeletal elements include induction, migration, condensation, differentiation, and proliferation, all of which require sophisticated genetic control. Recent discoveries provide evidence of several signaling pathways and their target genes contributing to cranial skeleton development. The interconnection between individual signaling cascades is extremely complex and creates an entire gene regulatory network. This thesis focuses primarily on genetic programmes controlling the development of neural crest-derived skeletal structures. Keywords: neural crest cells, osteogenesis, chondrogenesis, mesenchymal condensation, gene regulatory network
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