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Study of the hydration shell of vesicular systems based on ionic amphiphilic pairs
Rašticová, Barbora ; Szabová, Jana (referee) ; Mravec, Filip (advisor)
This bachelor thesis deals with the study of hydration shell of positively charged vesicular systems. The aim of the work was to monitor the hydration shell and to find out the amount of water molecules in the environment at different conditions of the membrane. Furthermore, a comparison of two selected fluorescent probes were studied. Positively charged vesicular systems composed of two types of surfactants were used, namely negatively charged SDS and positively charged CTAB. The two-chain positively charged surfactant was also added, resulting a positively charged vesicular systems. Three different concentrations of cholesterol were selected for the study and added to the system, namely 20, 40 and 60 mol. %. The study was performed by measuring the fluorescent emission as a function of temperature. The temperature range was from 10 to 80 °C. As a fluorescent probe Laurdan and Prodan were selected. For evaluation the method of generalized polarization was used. Due to its structure, Laurdan is mainly found in the membrane environment, so the method of two-wavelength generalized polarization, which includes fluorescence contributions only from the membrane, was sufficient for its evaluation. Compared to Laurdan, Prodan has a shorter hydrocarbon chain, so its distribution is not only in the membrane but also in the aqueous environment. Therefore, the method of three-wavelength generalized polarization, which also includes the contribution of fluorescence from the aqueous environment was used. The results showed that the behaviour of both probes is very similar. In all systems, the values of generalized polarization decreased with increasing temperature. Thus, at low temperatures, the membrane is in a solid ordered phase. With increasing temperature, it transforms into a liquid disordered phase. Thus, with increasing temperature, the number of water molecules increases. As the cholesterol concentration increased, the phase transition interval increased. The results also showed that the values of Prodan’s three wavelength generalized polarization are always higher than the values of Laurdan’s two wavelength generalized polarization.
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Interaction of negatively charged vesicular systems based on ionic amphiphilic pairs with polycations
Fardová, Lucie ; Venerová, Tereza (referee) ; Mravec, Filip (advisor)
This work is focused on the preparation of negatively charged vesicular systems from amphiphilic pairs deprived of counterions and their interaction with the polycation. First, vesicular systems were prepared from the surfactants sodium dodecyl sulfate and cetyltrimethylammonium bromide. The addition of cholesterol and phosphatidic acid stabilized and at the same time gained a negative charge. Subsequently, there was an interaction with the polycation diethylaminoethyl-dextran hydrochloride. The systems were investigated by the measuring of particle size, zeta potential, generalized polarization and anisotropy. The measurement of generalized polarization was enabled with the laurdan probe and measurement of anisotropy was performed with the introduction of the 1,6-diphenyl-1,3,5-hexatriene probe. The results indicate the successful preparation of stable, negatively charged systems that interacted with positive diethylaminoethyl-dextran hydrochloride, which affected the behavior of the outer membrane but not the inner. The systems were still stable.
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Influence of ionic strength on the properties of ionic amphiphilic pairs
Filipová, Lenka ; Smilek, Jiří (referee) ; Mravec, Filip (advisor)
The Bachelor thesis studies catanionic vesicle systems consisting of ion pair amphiphile (IPA) and their properties in the presence of ionic strength. Ion pair amphiphile was prepared from single-chained surfactants: cationic surfactant HTMAB (hexadecyltrimethylammonium bromide) and anionic surfactant SDS (sodium lauryl sulfate). Cationic double-chained surfactant DDAC (dimethyldioctadecylammonium chloride) was added in order to stabilize the vesicle system and make it positively charged. Cholesterol was also added to further stabilize the vesicle system. The system is considered to be relatively stable when consisting of 90 % IPA and 10 % DDAC with 43 mol.% cholesterol in a membrane. The stability of the system can be disrupted by external factors such as ionic strength. The Ionic strength was induced by NaCl solutions of varying concentrations (0.0, 0.5, 1.0, 2.0, 50.0, 100.0, 150.0 and 300.0 mM). The change of properties of a vesicle system, which was induced by ionic strength, was analyzed by electrophoretic and dynamic light scattering, fluorescence anisotropy, and generalized polarization. –potential was obtained by electrophoretic light scattering analysis which determines the stability of the system. Dynamic light scattering measurement resulted in the determination of the size of vesicles. The fluidity of vesicles’ membranes was examined by fluorescence anisotropy with DPH (1,6-diphenyl-1,3,5-hexatriene) as a probe. The hydration shell of vesicles was observed by generalized polarization with Laurdan (2-(dimethylamino)-6-dodecanoylnaphthalene) as a probe. As a result, it was found out that low ionic strength (0.5 to 2.0 mM) causes a decrease in the size of vesicles and high ionic strength (50.0 to 300.0 mM) causes vesicles to grow in size. –potential showed a consistent trend for the whole concentration series – its value rapidly decreasing with increasing ionic strength. The samples with the concentrations of salt 50.0 to 300.0 mM were considered unstable according to the –potential data. Fluorescence anisotropy decreases with increasing temperature and increasing ionic strength. The value of generalized polarization decreases with increasing temperature; hence there is more solvation of a vesicle membrane. The highest value of generalized polarization was measured when the concentration of sodium chloride was relatively high (from 50.0 to 300.0 mM), as a result of which the membrane was less hydrated and therefore, more organized.
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Interaction of negatively charged vesicular systems based on ionic amphiphilic pairs with polycations
Fardová, Lucie ; Venerová, Tereza (referee) ; Mravec, Filip (advisor)
This work is focused on the preparation of negatively charged vesicular systems from amphiphilic pairs deprived of counterions and their interaction with the polycation. First, vesicular systems were prepared from the surfactants sodium dodecyl sulfate and cetyltrimethylammonium bromide. The addition of cholesterol and phosphatidic acid stabilized and at the same time gained a negative charge. Subsequently, there was an interaction with the polycation diethylaminoethyl-dextran hydrochloride. The systems were investigated by the measuring of particle size, zeta potential, generalized polarization and anisotropy. The measurement of generalized polarization was enabled with the laurdan probe and measurement of anisotropy was performed with the introduction of the 1,6-diphenyl-1,3,5-hexatriene probe. The results indicate the successful preparation of stable, negatively charged systems that interacted with positive diethylaminoethyl-dextran hydrochloride, which affected the behavior of the outer membrane but not the inner. The systems were still stable.
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Study of the hydration shell of vesicular systems based on ionic amphiphilic pairs
Rašticová, Barbora ; Szabová, Jana (referee) ; Mravec, Filip (advisor)
This bachelor thesis deals with the study of hydration shell of positively charged vesicular systems. The aim of the work was to monitor the hydration shell and to find out the amount of water molecules in the environment at different conditions of the membrane. Furthermore, a comparison of two selected fluorescent probes were studied. Positively charged vesicular systems composed of two types of surfactants were used, namely negatively charged SDS and positively charged CTAB. The two-chain positively charged surfactant was also added, resulting a positively charged vesicular systems. Three different concentrations of cholesterol were selected for the study and added to the system, namely 20, 40 and 60 mol. %. The study was performed by measuring the fluorescent emission as a function of temperature. The temperature range was from 10 to 80 °C. As a fluorescent probe Laurdan and Prodan were selected. For evaluation the method of generalized polarization was used. Due to its structure, Laurdan is mainly found in the membrane environment, so the method of two-wavelength generalized polarization, which includes fluorescence contributions only from the membrane, was sufficient for its evaluation. Compared to Laurdan, Prodan has a shorter hydrocarbon chain, so its distribution is not only in the membrane but also in the aqueous environment. Therefore, the method of three-wavelength generalized polarization, which also includes the contribution of fluorescence from the aqueous environment was used. The results showed that the behaviour of both probes is very similar. In all systems, the values of generalized polarization decreased with increasing temperature. Thus, at low temperatures, the membrane is in a solid ordered phase. With increasing temperature, it transforms into a liquid disordered phase. Thus, with increasing temperature, the number of water molecules increases. As the cholesterol concentration increased, the phase transition interval increased. The results also showed that the values of Prodan’s three wavelength generalized polarization are always higher than the values of Laurdan’s two wavelength generalized polarization.
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Influence of ionic strength on the properties of ionic amphiphilic pairs
Filipová, Lenka ; Smilek, Jiří (referee) ; Mravec, Filip (advisor)
The Bachelor thesis studies catanionic vesicle systems consisting of ion pair amphiphile (IPA) and their properties in the presence of ionic strength. Ion pair amphiphile was prepared from single-chained surfactants: cationic surfactant HTMAB (hexadecyltrimethylammonium bromide) and anionic surfactant SDS (sodium lauryl sulfate). Cationic double-chained surfactant DDAC (dimethyldioctadecylammonium chloride) was added in order to stabilize the vesicle system and make it positively charged. Cholesterol was also added to further stabilize the vesicle system. The system is considered to be relatively stable when consisting of 90 % IPA and 10 % DDAC with 43 mol.% cholesterol in a membrane. The stability of the system can be disrupted by external factors such as ionic strength. The Ionic strength was induced by NaCl solutions of varying concentrations (0.0, 0.5, 1.0, 2.0, 50.0, 100.0, 150.0 and 300.0 mM). The change of properties of a vesicle system, which was induced by ionic strength, was analyzed by electrophoretic and dynamic light scattering, fluorescence anisotropy, and generalized polarization. –potential was obtained by electrophoretic light scattering analysis which determines the stability of the system. Dynamic light scattering measurement resulted in the determination of the size of vesicles. The fluidity of vesicles’ membranes was examined by fluorescence anisotropy with DPH (1,6-diphenyl-1,3,5-hexatriene) as a probe. The hydration shell of vesicles was observed by generalized polarization with Laurdan (2-(dimethylamino)-6-dodecanoylnaphthalene) as a probe. As a result, it was found out that low ionic strength (0.5 to 2.0 mM) causes a decrease in the size of vesicles and high ionic strength (50.0 to 300.0 mM) causes vesicles to grow in size. –potential showed a consistent trend for the whole concentration series – its value rapidly decreasing with increasing ionic strength. The samples with the concentrations of salt 50.0 to 300.0 mM were considered unstable according to the –potential data. Fluorescence anisotropy decreases with increasing temperature and increasing ionic strength. The value of generalized polarization decreases with increasing temperature; hence there is more solvation of a vesicle membrane. The highest value of generalized polarization was measured when the concentration of sodium chloride was relatively high (from 50.0 to 300.0 mM), as a result of which the membrane was less hydrated and therefore, more organized.
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