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Low-cost microextraction and preconcentration procedures for biomedical applications
Vašátko, Jan ; Diviš, Pavel (referee) ; Dvořák, Miloš (advisor)
This thesis focuses on low-cost microextraction techniques and their application for purification and preconcentration of biological samples, specifically on the experimental study of supported liquid membrane (SLM) extraction. The described microextraction technique uses commercially available filtration plates as the extraction units and allows the extraction of basic drugs from biological samples of urine and blood (in the form of dried blood spots). The experimental part includes the optimization of microextraction conditions of basic drugs from real samples through a SLM coupled in-line to lab-made capillary electrophoresis. The basic optimization of microextraction conditions involved selecting the appropriate organic phase for membrane impregnation (1:1 mixture of ENB and DHE), appropriate agitation speed for sample convection during extraction (1000 rpm), and optimal ratio of donor to acceptor volumes for high preconcentration of the analytes (400:15 µL). After basic optimization, the effect of donor alkalization with NaOH on extraction recovery (ER) was investigated. For all matrices used (saline solution, undiluted human urine samples, human capillary blood eluted from dry blood spots with deionized water), the highest ER values were achieved using a neutral donor and an acidic acceptor. The extraction time (60 minutes) was optimized based on the time profile of the microextraction for 120 minutes. This optimized microextraction method is suitable for the determination of basic drugs in real matrices with sufficient sample clean-up, preconcentration and ER values.
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Optimization of microextraction technique for analysis of water by chromatographic methods
Otrubová, Lucie ; Čabala, Radomír (advisor) ; Sobotníková, Jana (referee)
New liquid phase microextraction (LPME) has been optimized. Plastic adapter with tapered tip was used as extraction device. Concentration of analytes was determined by GC-MS. Face centered design was used to optimize LPME and the results were evaluated by Minitab 16 programme. Volume of sample, volume of extraction solvent, stirring rate, extraction time, ionic strength and time after microextraction were optimized. Response of system was defined as the sum of the peak relative areas. Toluene, tetrachlorethylene, ethylbenzene, xylenes, mesitylene and naphthalene were the studied analytes. Methylhexadecanoate was used as an internal standard. Optimal system conditions were as follows: 20 mL sample volume, 300 μL extraction solvent volume, 20 minutes, stirring speed 700 rpm, no addition of salt, and time after microextraction 3.5 minutes. Determination coefficient was 0.9700 and the lack-of-fit was insignificant which indicated good agreement of the model with the experimental data. The preconcentration factor ranged from 26 (tetrachlorethylene) to 39 (xylenes). The microextraction yield was varied from 39.5% (tetrachlorethylene) to 59.1% (p-xylene and m-xylene). The new method was tested by analyzing real samples of tap water, river water and water from the sewage treatment plant. The samples were...
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The application of high-efficiency separation methods for chiral and achiral separations
Šubová, Martina ; Bosáková, Zuzana (advisor) ; Jelínek, Ivan (referee) ; Fischer, Jan (referee)
In the first part of the doctoral thesis, the capillary electrophoresis was used to test the potential chiral separation properties of monosubstituted cyclodextrin derivatives, namely PEMEDA- and PEMPDA-β-cyclodextrins for the group of selected analytes. Both selectors exhibited excellent enantioseparation properties for N-boc-D,L-tryptophan, where the enantiomers were completely separated even at 0.5 mmol·l-1 concentration of the cyclodextrin derivative in the background electrolyte. However, the differences between the enantiodiscrimination properties of individual derivatives were minimal. The second test group consisted of two cyclodextrin derivatives, namely 2-O- and 3-O- cinnamyl-α-cyclodextrins. These derivatives are able to form supramolecular polymers in aqueous solutions that disintegrate at elevated temperature. The formation of these polymers was tested by NMR and DLS experiments. None of the tested cyclodextrin derivatives showed enantiodiscrimination properties towards a group of selected analytes. In the frame of antipredatory study, HPLC-MS/MS method working in HILIC mode was used for separation of ten pterin derivatives and riboflavin, which can be present as pigments in insects, reptiles or amphibians as a part of their warning coloration. The developed methodology was applied for...
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The application of high-efficiency separation methods for chiral and achiral separations
Šubová, Martina
In the first part of the doctoral thesis, the capillary electrophoresis was used to test the potential chiral separation properties of monosubstituted cyclodextrin derivatives, namely PEMEDA- and PEMPDA-β-cyclodextrins for the group of selected analytes. Both selectors exhibited excellent enantioseparation properties for N-boc-D,L-tryptophan, where the enantiomers were completely separated even at 0.5 mmol·l-1 concentration of the cyclodextrin derivative in the background electrolyte. However, the differences between the enantiodiscrimination properties of individual derivatives were minimal. The second test group consisted of two cyclodextrin derivatives, namely 2-O- and 3-O- cinnamyl-α-cyclodextrins. These derivatives are able to form supramolecular polymers in aqueous solutions that disintegrate at elevated temperature. The formation of these polymers was tested by NMR and DLS experiments. None of the tested cyclodextrin derivatives showed enantiodiscrimination properties towards a group of selected analytes. In the frame of antipredatory study, HPLC-MS/MS method working in HILIC mode was used for separation of ten pterin derivatives and riboflavin, which can be present as pigments in insects, reptiles or amphibians as a part of their warning coloration. The developed methodology was applied for...
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The application of high-efficiency separation methods for chiral and achiral separations
Šubová, Martina
In the first part of the doctoral thesis, the capillary electrophoresis was used to test the potential chiral separation properties of monosubstituted cyclodextrin derivatives, namely PEMEDA- and PEMPDA-β-cyclodextrins for the group of selected analytes. Both selectors exhibited excellent enantioseparation properties for N-boc-D,L-tryptophan, where the enantiomers were completely separated even at 0.5 mmol·l-1 concentration of the cyclodextrin derivative in the background electrolyte. However, the differences between the enantiodiscrimination properties of individual derivatives were minimal. The second test group consisted of two cyclodextrin derivatives, namely 2-O- and 3-O- cinnamyl-α-cyclodextrins. These derivatives are able to form supramolecular polymers in aqueous solutions that disintegrate at elevated temperature. The formation of these polymers was tested by NMR and DLS experiments. None of the tested cyclodextrin derivatives showed enantiodiscrimination properties towards a group of selected analytes. In the frame of antipredatory study, HPLC-MS/MS method working in HILIC mode was used for separation of ten pterin derivatives and riboflavin, which can be present as pigments in insects, reptiles or amphibians as a part of their warning coloration. The developed methodology was applied for...
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The application of high-efficiency separation methods for chiral and achiral separations
Šubová, Martina ; Bosáková, Zuzana (advisor) ; Jelínek, Ivan (referee) ; Fischer, Jan (referee)
In the first part of the doctoral thesis, the capillary electrophoresis was used to test the potential chiral separation properties of monosubstituted cyclodextrin derivatives, namely PEMEDA- and PEMPDA-β-cyclodextrins for the group of selected analytes. Both selectors exhibited excellent enantioseparation properties for N-boc-D,L-tryptophan, where the enantiomers were completely separated even at 0.5 mmol·l-1 concentration of the cyclodextrin derivative in the background electrolyte. However, the differences between the enantiodiscrimination properties of individual derivatives were minimal. The second test group consisted of two cyclodextrin derivatives, namely 2-O- and 3-O- cinnamyl-α-cyclodextrins. These derivatives are able to form supramolecular polymers in aqueous solutions that disintegrate at elevated temperature. The formation of these polymers was tested by NMR and DLS experiments. None of the tested cyclodextrin derivatives showed enantiodiscrimination properties towards a group of selected analytes. In the frame of antipredatory study, HPLC-MS/MS method working in HILIC mode was used for separation of ten pterin derivatives and riboflavin, which can be present as pigments in insects, reptiles or amphibians as a part of their warning coloration. The developed methodology was applied for...
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Low-cost microextraction and preconcentration procedures for biomedical applications
Vašátko, Jan ; Diviš, Pavel (referee) ; Dvořák, Miloš (advisor)
This thesis focuses on low-cost microextraction techniques and their application for purification and preconcentration of biological samples, specifically on the experimental study of supported liquid membrane (SLM) extraction. The described microextraction technique uses commercially available filtration plates as the extraction units and allows the extraction of basic drugs from biological samples of urine and blood (in the form of dried blood spots). The experimental part includes the optimization of microextraction conditions of basic drugs from real samples through a SLM coupled in-line to lab-made capillary electrophoresis. The basic optimization of microextraction conditions involved selecting the appropriate organic phase for membrane impregnation (1:1 mixture of ENB and DHE), appropriate agitation speed for sample convection during extraction (1000 rpm), and optimal ratio of donor to acceptor volumes for high preconcentration of the analytes (400:15 µL). After basic optimization, the effect of donor alkalization with NaOH on extraction recovery (ER) was investigated. For all matrices used (saline solution, undiluted human urine samples, human capillary blood eluted from dry blood spots with deionized water), the highest ER values were achieved using a neutral donor and an acidic acceptor. The extraction time (60 minutes) was optimized based on the time profile of the microextraction for 120 minutes. This optimized microextraction method is suitable for the determination of basic drugs in real matrices with sufficient sample clean-up, preconcentration and ER values.
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Optimization of microextraction technique for analysis of water by chromatographic methods
Otrubová, Lucie ; Čabala, Radomír (advisor) ; Sobotníková, Jana (referee)
New liquid phase microextraction (LPME) has been optimized. Plastic adapter with tapered tip was used as extraction device. Concentration of analytes was determined by GC-MS. Face centered design was used to optimize LPME and the results were evaluated by Minitab 16 programme. Volume of sample, volume of extraction solvent, stirring rate, extraction time, ionic strength and time after microextraction were optimized. Response of system was defined as the sum of the peak relative areas. Toluene, tetrachlorethylene, ethylbenzene, xylenes, mesitylene and naphthalene were the studied analytes. Methylhexadecanoate was used as an internal standard. Optimal system conditions were as follows: 20 mL sample volume, 300 μL extraction solvent volume, 20 minutes, stirring speed 700 rpm, no addition of salt, and time after microextraction 3.5 minutes. Determination coefficient was 0.9700 and the lack-of-fit was insignificant which indicated good agreement of the model with the experimental data. The preconcentration factor ranged from 26 (tetrachlorethylene) to 39 (xylenes). The microextraction yield was varied from 39.5% (tetrachlorethylene) to 59.1% (p-xylene and m-xylene). The new method was tested by analyzing real samples of tap water, river water and water from the sewage treatment plant. The samples were...
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