|
|
Hydrogels modified by amphiphilic structures
Heger, Richard ; Sedlařík, Vladimír (referee) ; Kráčalík, Milan (referee) ; Pekař, Miloslav (advisor)
The submitted dissertation deals with the influence of amphiphilic structures on hydrogel properties. Additions of various amphiphilic substances associated with the formation of highly ordered structures affect the mechanical, transport and structural properties of hydrogels. The main inspiration for this type of work was living tissue, more precisely the extracellular matrix, which is often mimicked by hydrocolloids, and its high orderliness is responsible for its unique properties. The knowledge obtained from this tissue was applied to the hydrogel systems studied in this work. Various cross-linked hydrogel matrices (physically cross-linked agarose and gelatin, ionically cross-linked alginate and chemically cross-linked mixture of polyvinyl alcohol and chitosan) were suitable representatives for this work. These hydrogel systems were modified by the addition of various amphiphilic substances. The human body’s own phospholipid, lecithin, or variously charged more classic surfactants (CTAB, SDS and Triton X-100). Experimentally, this work is divided into three areas, the study of mechanical properties using rheology, the description of transport properties via release and flow experiments using various model drugs (rhodamine 6G, eosin B, amido black 10B, methylene blue and riboflavin), and morphological characterization using SEM. The characterization of hydrogel systems was supported by other techniques used in this work, such as drying and swelling experiments or gas sorption.
|
|
|
Viscoelastic properties of hydrogels depending on relative humidity
Kouřilová, Ludmila ; Heger, Richard (referee) ; Smilek, Jiří (advisor)
This bachelor thesis is mainly aimed on the determination of the dependence of the viscoelastic properties of physically crosslinked hydrogels on the relative humidity controlled by humidity cell (as an accessory to a rotary rheometer), or the desiccator with the drying medium. The main objective was to optimise the methodology of the humidity cell for the rheological determination of the viscoelastic properties of hydrogel materials as a function of relative humidity and to verify experimental setup on the agarose hydrogel. The results showed that the agarose hydrogel gradually loses its dispersion medium after exposure to chosen relative humidity, resulting in a loss of contact between the upper rheometer sensor and the sample when measured with the standard measurement gap control setting, which is constant during the measurement. The setting of the control of normal force proved to be an appropriate solution, which has led to a gradual reduction in the height of the upper rheometer sensor in an attempt to keep the normal force at the desired level during the drying of the hydrogel. A humidity cell proves to be an appropriate method for determining the dependence of the viscoelastic properties of hydrogels on relative humidity. Unlike the use of a desiccator with drying medium, the drying of the hydrogel sample does not result in such rapid drying that it breaks the texture on its surface. Another advantage of a humidity cell is the ability to maintain the desired relative humidity value even if the gel begins to release dispersion medium into its surroundings, which was not possible with a desiccator with drying medium.
|
|
|
Influence of conditions on hydrogel preparation
Heger, Richard ; Kalina, Michal (referee) ; Mravec, Filip (advisor)
This work is focused on testing the influence of conditions, more precisely pH, during the creation of hydrogels that were prepared through the hydration of powdery mixtures, by another name solid-mixture way. The hydrogel system was made from a polyelectrolyte, more accurately sodium hyaluronate and a cationic surfactant, CTAB. The influence of pH was studied through observation and rheology. For measuring purposes, the hyaluronan with the molecular weight of 600-800 kDa was used. The system was examined via a series of buffers with the pH of 3,5-11. The gels were dyed by Sudan III for better observability and description. It was found that the best way of adding an active substance was by adding a dye directly into a powdery mixture. The observed properties of the gels didn’t change even after the gels were modified to the ionic strength of a physiological saline solution (0,15 M).
|
|
|
Study on relaxation properties of hydrogels by using rheometer
Obrusníková, Klára ; Heger, Richard (referee) ; Smilek, Jiří (advisor)
This thesis deals with viscoelastic (specifically relaxation) properties of a selected hydrogel system using three interval thixotropy tests. Collagen hydrogel was chosen as the investigated material and its viscoelastic properties were studied based on time and different storage temperatures. The collagen gel is thixotropic; its structure is disrupted when subjected to deformation and it is able to reform (relax) to a certain rate afterwards. As for time dependency, the collagen hydrogel shows great stability, there were almost no changes in mechanical properties over two months. The temperature dependency is, however, quite significant. When subjected to temperatures below the freezing point, the structure of collagen stabilises, which is expressed by an increase of the complex modulus, when subjected to temperatures close to the human body temperature, the structure degrades, which is expressed by a decrease of the complex modulus. The results show that the collagen gel relaxes best when kept at room temperature, but it simultaneously exhibits the lowest elasticity. On the contrary, when kept at the temperature around 5 °C, the gel exhibits the highest elasticity and relaxes the worst. The optimal temperature for the storage of the given gel seems to be around 5 °C, according to the results.
|
|
|
Study on flow and viscoelastic properties of laboratory prepared synovial fluids by macrorheological techniques
Veldamonová, Aneta ; Heger, Richard (referee) ; Smilek, Jiří (advisor)
This bachelor thesis deals with preparation and characterization of synthetic synovial fluid. Preparation was focused mostly on finding proper ratios of substances existing in real synovial fluid which have influence on viscoelastic properties. Based on study of literature, these substances are hyaluronic acid, lubricin, phospholipids and proteins. Samples of real synovial fluid from horse hock acquired from University of veterinary and pharmaceutical sciences Brno were tested for comparation with synthetically prepared synovial fluid. Both synthetic and real synovial fluid were characterized by macrorheological techniques. The experimentally obtained data were then compared with data from the patent on which the preparation of synthetic synovial fluid was based on. Thermogravimetry and isothermal thermogravimetry were used as additional method for the study of moisture and water binding of synovial fluids.
|
|
|
Monitoring the pH change in the phase-separated hydrogel systems
Heger, Richard ; Smilek, Jiří (referee) ; Mravec, Filip (advisor)
This thesis pursues monitoring of pH changes and description of properties in phase–separated hydrogels prepared by interaction of polyelectrolyte and oppositely charged surfactants. For the purposes of this work, all hydrogels were prepared by the interaction of hyaluronan with Septonex. All hydrogels were exposed to pH changes (4–9). Changes in pH were being monitored using spectroscopic indicators, methyl orange, methyl red, bromothymol blue and phenolphtalein. The pre– and post– pH changes in properties were compared using rheological methods. Additional information was gathered through thermogravimetric analysis. By these methods it was proved that the changes in the pH can modify the mechanical properties and partly the internal structure of the hydrogels. Rheological tests show, that from the application point of view, the most interesting hydrogels are observed at pH 9 which have the strongest bonds but have low permeability and hydrogels described at pH 7 which are much softer and are capable of absorbing large amounts of water.
|
|
|
Viscoelastic properties of hydrogels depending on relative humidity
Kouřilová, Ludmila ; Heger, Richard (referee) ; Smilek, Jiří (advisor)
This bachelor thesis is mainly aimed on the determination of the dependence of the viscoelastic properties of physically crosslinked hydrogels on the relative humidity controlled by humidity cell (as an accessory to a rotary rheometer), or the desiccator with the drying medium. The main objective was to optimise the methodology of the humidity cell for the rheological determination of the viscoelastic properties of hydrogel materials as a function of relative humidity and to verify experimental setup on the agarose hydrogel. The results showed that the agarose hydrogel gradually loses its dispersion medium after exposure to chosen relative humidity, resulting in a loss of contact between the upper rheometer sensor and the sample when measured with the standard measurement gap control setting, which is constant during the measurement. The setting of the control of normal force proved to be an appropriate solution, which has led to a gradual reduction in the height of the upper rheometer sensor in an attempt to keep the normal force at the desired level during the drying of the hydrogel. A humidity cell proves to be an appropriate method for determining the dependence of the viscoelastic properties of hydrogels on relative humidity. Unlike the use of a desiccator with drying medium, the drying of the hydrogel sample does not result in such rapid drying that it breaks the texture on its surface. Another advantage of a humidity cell is the ability to maintain the desired relative humidity value even if the gel begins to release dispersion medium into its surroundings, which was not possible with a desiccator with drying medium.
|
|
|
Study on relaxation properties of hydrogels by using rheometer
Obrusníková, Klára ; Heger, Richard (referee) ; Smilek, Jiří (advisor)
This thesis deals with viscoelastic (specifically relaxation) properties of a selected hydrogel system using three interval thixotropy tests. Collagen hydrogel was chosen as the investigated material and its viscoelastic properties were studied based on time and different storage temperatures. The collagen gel is thixotropic; its structure is disrupted when subjected to deformation and it is able to reform (relax) to a certain rate afterwards. As for time dependency, the collagen hydrogel shows great stability, there were almost no changes in mechanical properties over two months. The temperature dependency is, however, quite significant. When subjected to temperatures below the freezing point, the structure of collagen stabilises, which is expressed by an increase of the complex modulus, when subjected to temperatures close to the human body temperature, the structure degrades, which is expressed by a decrease of the complex modulus. The results show that the collagen gel relaxes best when kept at room temperature, but it simultaneously exhibits the lowest elasticity. On the contrary, when kept at the temperature around 5 °C, the gel exhibits the highest elasticity and relaxes the worst. The optimal temperature for the storage of the given gel seems to be around 5 °C, according to the results.
|
|
|
Study on flow and viscoelastic properties of laboratory prepared synovial fluids by macrorheological techniques
Veldamonová, Aneta ; Heger, Richard (referee) ; Smilek, Jiří (advisor)
This bachelor thesis deals with preparation and characterization of synthetic synovial fluid. Preparation was focused mostly on finding proper ratios of substances existing in real synovial fluid which have influence on viscoelastic properties. Based on study of literature, these substances are hyaluronic acid, lubricin, phospholipids and proteins. Samples of real synovial fluid from horse hock acquired from University of veterinary and pharmaceutical sciences Brno were tested for comparation with synthetically prepared synovial fluid. Both synthetic and real synovial fluid were characterized by macrorheological techniques. The experimentally obtained data were then compared with data from the patent on which the preparation of synthetic synovial fluid was based on. Thermogravimetry and isothermal thermogravimetry were used as additional method for the study of moisture and water binding of synovial fluids.
|
|
|
Monitoring the pH change in the phase-separated hydrogel systems
Heger, Richard ; Smilek, Jiří (referee) ; Mravec, Filip (advisor)
This thesis pursues monitoring of pH changes and description of properties in phase–separated hydrogels prepared by interaction of polyelectrolyte and oppositely charged surfactants. For the purposes of this work, all hydrogels were prepared by the interaction of hyaluronan with Septonex. All hydrogels were exposed to pH changes (4–9). Changes in pH were being monitored using spectroscopic indicators, methyl orange, methyl red, bromothymol blue and phenolphtalein. The pre– and post– pH changes in properties were compared using rheological methods. Additional information was gathered through thermogravimetric analysis. By these methods it was proved that the changes in the pH can modify the mechanical properties and partly the internal structure of the hydrogels. Rheological tests show, that from the application point of view, the most interesting hydrogels are observed at pH 9 which have the strongest bonds but have low permeability and hydrogels described at pH 7 which are much softer and are capable of absorbing large amounts of water.
|
guest ::
