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Biocomposite material for 3D print in the field of regenerative medicine
Chaloupková, Kateřina ; Obruča, Stanislav (referee) ; Přikryl, Radek (advisor)
The presented thesis deals with preparation of material for use in regenerative medicine based on poly(3-hydroxybutyrate) and its characterization. In addition to poly (3-hydroxybutyrate), there were used other materials lactic acid (PLA), tricalcium phosphate (TCP) and two types of plasticizers Citroflex®B-6 (CB6) and Syncroflex3114 (S3114). These materials were selected based on their biocompatibility and, in the case of TCP, also bioactivity. TCP allows new bone to grow on the surface of the scaffold. PLA was used to improve the mechanical properties of the material. Both plasticizers have been used to improve the processability of the material. Theoretical part of this work contains a literature review describing basic information about used materials. Aim of the experimental part is to prepare the material, characterization of properties and determination of printability on a 3D printer. The material is examined for thermal properties by thermogravimetric analysis and differential scanning calorimetry. This work also deals with the matter of 3D printing, especially FDM technology. It has been found that materials containing the syncroflex plasticizer are better processed and therefore printed on a 3D printer. The printability tests performed are temperature towers and filling studies. Printed samples were subjected to mechanical tests of tensile and bending tests. Experiments of cytotoxicity and biocompatibility of the material were also performed. Within the work, TCP particles were characterized using a particle size analyzer. The average TCP particle size is 10,76 µm. Using SEM-EDX, the distribution of TCP in sample filaments was subsequently observed, where it was found that by mixing TCP particles with the remaining components of materials, TCP particles agglomerate into formations up to 20 µm in size. Roughness of materials was determined by confocal microscopy. Cytotoxicity was also tested in the extracts of samples on mouse fibroblasts. Cytotoxicity was determined by metabolic activity assay and light microscopy. The metabolic activity test proved the biocompatibility of the observed materials; therefore, it was possible to perform cell proliferation and biocompatibility tests directly on the samples. Assays were performed using human mesenchymal stem cells. DNA quantification was used to determine cell proliferation. Shape of cells was subsequently observed by confocal microscopy. Tests confirmed growth of cells and their appropriate shape. Stem cell differentiation into bone was performed by measuring alkaline phosphatase activity.
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Biocomposite material for 3D print in the field of regenerative medicine
Chaloupková, Kateřina ; Obruča, Stanislav (referee) ; Přikryl, Radek (advisor)
The presented thesis deals with preparation of material for use in regenerative medicine based on poly(3-hydroxybutyrate) and its characterization. In addition to poly (3-hydroxybutyrate), there were used other materials lactic acid (PLA), tricalcium phosphate (TCP) and two types of plasticizers Citroflex®B-6 (CB6) and Syncroflex3114 (S3114). These materials were selected based on their biocompatibility and, in the case of TCP, also bioactivity. TCP allows new bone to grow on the surface of the scaffold. PLA was used to improve the mechanical properties of the material. Both plasticizers have been used to improve the processability of the material. Theoretical part of this work contains a literature review describing basic information about used materials. Aim of the experimental part is to prepare the material, characterization of properties and determination of printability on a 3D printer. The material is examined for thermal properties by thermogravimetric analysis and differential scanning calorimetry. This work also deals with the matter of 3D printing, especially FDM technology. It has been found that materials containing the syncroflex plasticizer are better processed and therefore printed on a 3D printer. The printability tests performed are temperature towers and filling studies. Printed samples were subjected to mechanical tests of tensile and bending tests. Experiments of cytotoxicity and biocompatibility of the material were also performed. Within the work, TCP particles were characterized using a particle size analyzer. The average TCP particle size is 10,76 µm. Using SEM-EDX, the distribution of TCP in sample filaments was subsequently observed, where it was found that by mixing TCP particles with the remaining components of materials, TCP particles agglomerate into formations up to 20 µm in size. Roughness of materials was determined by confocal microscopy. Cytotoxicity was also tested in the extracts of samples on mouse fibroblasts. Cytotoxicity was determined by metabolic activity assay and light microscopy. The metabolic activity test proved the biocompatibility of the observed materials; therefore, it was possible to perform cell proliferation and biocompatibility tests directly on the samples. Assays were performed using human mesenchymal stem cells. DNA quantification was used to determine cell proliferation. Shape of cells was subsequently observed by confocal microscopy. Tests confirmed growth of cells and their appropriate shape. Stem cell differentiation into bone was performed by measuring alkaline phosphatase activity.
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