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Adhesion, growth and differentiation of osteoblast-like cells on materials for bone implants
Doubková, Martina ; Bačáková, Lucie (advisor) ; Filová, Eva (referee)
This thesis focuses on testing and improving Ti-6Al-4V ELI biomaterials, which are currently one of the most used titanium alloys in biomedicine (predominantly in orthopaedics and dentistry), in cooperation with research institutions and private companies developing and producing such materials. The metallic samples were previously modified by plasma electrolytic oxidation (PEO) with use of electrolytes of a different composition to induce development of a homogeneous TiO2 layer on its surface. In vitro interactions of human osteoblast-like cell line Saos-2 with the surface of Ti-6Al-4V ELI alloy samples are investigated. Initial cell attachment, spreading, morphology, cell population density, viability, calcium deposition and expression of selected osteogenic markers, e.g. collagen type I, alkaline phosphatase and osteocalcin, were evaluated on cultured cells. The cells behavior were then correlated with physicochemical properties of the material surface, such as its topography, roughness, wettability, surface layer chemical composition etc. The results are also compared with those obtained in cells cultured on control samples of untreated alloys as well as microscopic glass coverslips and bottom of standard polystyrene cell culture wells. The aim of this thesis is to select the most promising...
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Adhesion, growth and differentiation of skin cells on nanofibrous polymer membranes
Pajorová, Júlia ; Bačáková, Lucie (advisor) ; Eckhardt, Adam (referee)
Our study contributes to the tissue engineering, mainly to the construction of appropriate scaffolds for regeneration of damaged skin. Simultaneously, it brings valuable insights for basic research in the field of molecular mechanisms of adhesion, proliferation and phenotypic maturation of cells and the control of the cell behavior through the cell extracellular matrix (ECM), represented by synthetic nanofibrous material. Nanofibrous polylactic-co-glycolic acid (PLGA) membranes were prepared by needle-less electrospinning technology. These membranes were further modified with cell adhesion-mediating biomolecules, e.g. collagen, fibronectin and fibrin in order to increase their affinity to colonizing cells. Adhesion, growth and differentiation of keratinocytes (HaCaT) and fibroblasts, i.e. major cell types of epidermis and dermis, were evaluated on these nanofibrous membranes. The results show that the membrane modification using fibrin structures improved adhesion and proliferation of human dermal fibroblasts. The collagen structure on the surface of membranes improved the adhesion and proliferation of human HaCaT keratinocytes. Furthermore, fibrin structure stimulated fibroblasts to produce collagen, which is a major component of ECM in the natural skin dermis. Fibronectin enhanced cell attachment...
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The Growth of vascular and skin cells on polymer materials for tissue engineering
Bačáková, Markéta ; Bačáková, Lucie (advisor) ; Smetana, Karel (referee) ; Daniel, Matej (referee)
The ideal vascular or skin substitute is able to simulate the functions of original vascular or skin tissue. To reach this goal, the tissue substitute should be based on a biomaterial scaffold of an appropriate structure and desirable physical and chemical properties. These properties strongly influence successful implantation of the substitute to the patient's organism, substitute durability in the organism, and the desired colonization of the scaffolds with cells. These properties have a great impact on the adhesion, proliferation, differentiation, and desired phenotypic maturation of cells. Most of the biomaterials used for constructing clinically used tissue substitutes do not have appropriate properties for sufficient cell colonization, and thus their surface modification is needed. This thesis focuses on the improvement of biomaterial surface properties for successful cell colonization by plasma treatment, or by grafting and coating biomaterials with bioactive substances and extracellular matrix proteins. The modification of polyethylene (PE) foils by Ar+ plasma discharge showed a positive effect on the spreading, proliferation, and phenotypic maturation of vascular smooth muscle cells (VSMC). Subsequent grafting of the plasma-activated surface with bioactive substances further influenced cell...
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Role of endothelial and vascular smooth muscle cells in the origin, progression and therapy of vascular diseases
Chlupáč, Jaroslav ; Bačáková, Lucie (advisor) ; Piťha, Jan (referee) ; Sedmera, David (referee)
Introduction: Vascular surgery for atherosclerosis is confronted by the lack of a suitable bypass material. Synthetic vascular prostheses include polyethylene terephthalate (PET) and expanded polytetrafluoroethylene (ePTFE). However, these materials become thrombosed in small-caliber applications (<6 mm) because of the lack of an endothelium. The objectives of this study were to make modifications to clinically-used PET vascular prostheses with tissue-engineered surfaces to improve their bio-compatibility towards vascular smooth muscle cells (VSMC) and endothelial cells (EC). Methods: Blood coagulation protein fibrin (Fb) and extracellular matrix proteins collagen (Co), laminin (LM) and fibronectin (FN) were used. Cell adhesive assemblies were prepared: Co, Co/LM, Co/FN, Co/Fb, Co/Fb/FN. Cell culture experiments were performed: (1) planar static, (2) planar dynamic with simulation of blood flow, (3) tubular dynamic, and (4) animal porcine implantation. Results: The growth of EC and VSMC on commercial prostheses (ePTFE, PET and PET/Co) was low. The growth of both cell types was lower on PET/Co than on PET. After modification with protein assemblies, the highest numbers of EC were reached on PET/Co and on PET/Co +Co/Fb. There was no difference in the densities of VSMC among various assemblies. The...
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Application of the stem cells in bone tissue engineering
Kročilová, Nikola ; Bačáková, Lucie (advisor) ; Eckhardt, Adam (referee)
Problems with musculoskeletal system, such as of developmental disorders, fractures or damage of the bone by age, inflammatory or tumor diseases, are still increasing in orthopaedics. Sometimes the bone tissue is not capable to completely regenerate to exert its physiological function in the organism. For this reason, using the bone replacements is necessary and common nowadays. Despite of an intensive research and testing of a wide range of the potential biomaterials and their combinations, the usage of metal materials for construction of the bone implants, still remains to be the gold standard. Ti-6Al-4V alloy is one of the commercialy used metal materials, which is known for the high mechanical and chemical resistance and a good biocompatibility. For a good biological response of the patient's organism for the bone implant, is an ability of osteointegration into the surrounding bone tissue, the key. This ability can be influenced in the case of the metals, by their surface structure. As it is known from earlier studies, the surface topography of the material is very important for the adhesion and proliferation of the bone cells, which are able to discriminate, very sensitively, between various stages of the material surface roughness. For this reason we have focused on studying of an influence...
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The biocompatibility and potential cytotoxicity of materials for joint replacement manufacturing and coating
Kopová, Ivana ; Bačáková, Lucie (advisor) ; Hubálek Kalbáčová, Marie (referee) ; Jendelová, Pavla (referee)
Currently used prostheses for total joint replacement still have numerous disadvantages: extreme stiffness or elastic modulus of the bulk metallic material; insufficient integration of the implant into the host bone; and a high wear and corrosion rate, which causes an accumulation of mostly metallic or polymeric wear debris. Because of these reasons, many patients experience increasing local pain, swelling, allergic reactions, and inflammation resulting in bone loss and the aseptic loosening of the implant leading to the need for painful and expensive revision surgery. To address the mechanical issues of commonly used orthopaedic alloys, this thesis presents the development of the new β-type titanium alloy Ti-35Nb-7Zr-6Ta-2Fe-0.5Si with a relatively low elastic modulus (up to 85 GPa), increased tensile strength (880 MPa), and enhanced biocompatibility and osteoconductivity. Considering the generally low osteoinductivity of metallic implants, various surface modifications and coatings have been developed to improve the cell-material interaction, e.g. carbon-based coatings. Among these coatings, C60 fullerene layers have emerged as a great candidate for coating orthopaedic implants due to their therapeutic potential in arthritis. The potential cytotoxicity and DNA damage response of fullerenes have...
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Cell-biomaterial interactions in hard and soft tissue engineering
Zárubová, Jana ; Bačáková, Lucie (advisor) ; Mikšík, Ivan (referee) ; Slepička, Petr (referee)
Tissue engineering is an interdisciplinary field which aims to create substitutes of damaged tissues by combining cells with biomaterials. Cells are extremely sensitive to their microenvironment and so the cell response to biomaterials can be regulated by different extrinsic stimuli and alterations of biomaterial properties. Successful implant integration into the tissue can therefore be promoted by appropriate surface roughness, chemical composition, adhesion ligand density, as well as the availability of growth factors. This thesis mainly focuses on the development of orthopedic replacements and the improvement of the currently used blood vessel prostheses. Through the study of cell-biomaterial interactions, it was demonstrated that superimposed topography with features ranging from the nano to micro scale promotes cell spreading, proliferation, and the metabolic activity of osteoblast-like cells. Moreover, when comparing the chemical composition of biomaterials for orthopedic implants, higher osteoblast densities were observed on composites with 5-15 vol. % of calcium phosphate nanoparticles, while concentrations of 25 vol. % did not support cell proliferation. Cell viability, however, was not affected. In vivo, a more intensive formation of new bone tissue, was found on samples containing...
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Cell growth on biomaterials for skin replacements and wound dressings
Kudláčková, Radmila ; Bačáková, Lucie (advisor) ; Rösel, Daniel (referee) ; Eckhardt, Adam (referee)
Tissue engineering is an emerging interdisciplinary field developing new ways of treatment of patient's tissue defects using artificial substitutes. Skin tissue engineering is developing skin substitutes and wound dressings that would replace current treatment using autologous, allogeneic or xenogenic substitutes. There are high demands on materials which should serve as a scaffolds for dermal fibroblasts and keratinocytes. They must be non-cytotoxic and biodegradable with a rate proportional to formation of a new tissue. The materials should support adhesion and proliferation of the cells and even they could release growth factors and antimicrobial substance to enhance healing and new tissue formation. In this master thesis, the cell adhesion and proliferation were evaluated on sodium carboxymethyl cellulose (Hcel® NaT), poly-ε-caprolactone (PCL), poly-L-lactide-co-ε-caprolactone (PLA/PCL) and cellulose acetate (AC) nanofiber membranes. Primary human dermal fibroblasts and HaCaT cell line keratinocytes were selected for evaluation. The cell adhesion was observed by fluorescent microscopy, the proliferation was determined by metabolic assay (WST-1) and the material cytotoxicity was evaluated in xCELLigence® system. Materials did not show cytotoxic effects on the cells. However, the materials did...
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Interactions of vascular and bone cells with bioactive polymers for construction of tissue replacements
Pařízek, Martin ; Bačáková, Lucie (advisor) ; Smetana, Karel (referee) ; Hrubý, Martin (referee)
This work deals with the interaction of cells with surface-modified existing or newly created materials developed for vascular and bone tissue engineering, and also for controlled drug delivery into implants. In the first part of this work, we modified the surface of the polyethylene foil by Ar plasma, and then we grafted them with bioactive molecules (glycine, polyethylene glycol, albumin) and with C or Au nanoparticles. These modifications improved the chemical and physical characteristics of the material for the adhesion and growth of vascular smooth muscle cells (VSMC), and also for their phenotypic maturation towards the contractile fenotype. In future, these modifications can be also used for material currently used for fabrication of clinically used vascular prostheses in order to increase their biocompatibility. The aim of the second part of this work was to develop a perivascular drug-delivery system that would release the antiproliferative drug Sirolimus. This perivascular system is designed to be wrapped around a venous graft, implanted to the arterial position, such as in the case of the aortocoronary bypass. The system comprises a polyester mesh, which ensures the mechanical stability of the system and of the venous wall, and a copolymer of L-lactide and ε-caprolactone (Purasorb), serving as a...
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Adhesion, growth and potential immune activation of cells on metallic materials for bone implants.
Straňavová, Lucia ; Bačáková, Lucie (advisor) ; Filová, Elena (referee)
The contemporary orthopaedics and traumatology of the musculoskeletal system and stomatology have been witnessing a substantial increase in the number of surgeries using metallic implants. The issue of reconstruction of bone defects covers a large area of study, where the surface properties of the implants are extremely important. Bone defects often occur as a result of open fractures, radical cancer treatment or limb lengthening, which is very common in paediatric orthopaedics. In the treatment of these conditions, the surface of the applied materials should provide a favorable environment for bone cells and support bone formation. In endoprosthetics it is highly desirable to achieve the strongest possible fixation between the implant surface and the bone. During the surgery, primary stability of the implant fixation is ensured by the proper positioning of the implant, based on the appropriate shape of the implant and the quality of bone cut. The initial stability is only temporary, being estimated to last approximately three months. After this period, the secondary stability starts, determined by the bone ingrowth into the implant surface structure. Osteogenic differentiation and extracellular matrix (ECM) mineralization can be enhanced by the presence of bone morphogenetic proteins (BMPs),...
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