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Usage of physical-chemical methods for the study of interaction of humic substances with the plant cutisles
Rampáčková, Eliška ; Sedláček, Petr (referee) ; Smilková, Marcela (advisor)
This bachelor’s thesis deals with the study of interaction (or binding or adsorption) of plant cuticle with potassium lignohumate, as a liquid agriculture product used in the field of foliar fertilization, which belongs to the most used agronomic applications in general. The studied materials became the plant cuticle, which forms upper part of plants and potassium lignohumate (commercially Lignohumate), which is widely used thanks to its properties, which allow to increase the quality, growth and profitability of the crops. The aim of this bachelor’s thesis was to investigate the binding of compounds to plant cuticles, useful methods for this field of research and the use of thermal methods (precisely isothermal microcalorimetry and thermogravimetry). The next step was to use this instrumentation as a physicochemical method for assessing the ability of Lignohumate to bind to plant cuticles.
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Optimalization of experimental method for study on penetration of humic acids into leaves.
Smilková, Marcela ; Pekař, Miloslav (referee) ; Sedláček, Petr (advisor)
This bachelor’s thesis is focused on the study of penetration of humic substances trough the plant cuticle. The main objective of the thesis aimed at a literature search on foliar fertilization and transport of substances in the plant leaves. According to the literature search, experimental technique was suggested and tested in order to study penetration of humic substances through the leaf cuticle. The method consists of observation of diffusion transport of humic acids between two inert agarose gels separated by the plant cuticle. Cuticles were prepared by the means of three different isolation procedures.
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Transport of humic substances through plant cuticle
Smilková, Marcela ; Salaš, Petr (referee) ; Weidlich, Tomáš (referee) ; Klučáková, Martina (advisor)
Doctoral Thesis is aimed on the transport of liquid preparations chemically based on potassium lignohumate through plant cuticles commonly utilized in agricultural applications. Firstly, the thesis deals with optimization and correct mathematical description of diffusion experiments. Transport (diffusion) experiments have been realized in model hydrogel media based on linear polysaccharide – chemically inert agarose. Diffusion experiments have been realized by two independent approaches (diffusion models) – free diffusion of lignohumate in hydrogel and diffusion pair (hydrogel-hydrogel), where one of these was enriched by lignohumate in contrast with the second one. Plant cuticle, as the major barrier on the leaves, isolated from Prunus laurocerasus, was used as porous membrane in diffusion experiments. The main aim of Ph.D. thesis was the characterization of barrier properties of cuticles, which are the most limiting barrier regulating the transport of lignohumate in/out the leaves during foliar fertilization. These experimental problems have been solved by diffusion experiments and by their proper mathematical description, especially by the determination of fundamental diffusion parameters such as effective diffusion coefficients. These parameters have been used for the modelling of concentration profiles in hydrogels and comparison with experimental data. Significant part of thesis is aimed on the determination of physico-chemical properties of plant cuticles and hydrogels matrixes utilized as model diffusion environment. These characteristics are subsequently correlated with transport (diffusion) parameters. Plant cuticles have been isolated from Prunus laurocerasus leaves and then were characterized by relevant instrumentation notably with respect to their structure and penetration through of lignohumate. Hydrogels have been characterized with respect to mechanical (viscoelastic) (rheology), morphological e.g. porosimetry) and structural (scanning electron microscopy) properties. Mentioned properties have direct link to transport processes ongoing in these materials. Next part of doctoral thesis is aimed on the proper and correct interpretation of experimental results obtained from glass-house experiments. During these experiments, hydrogels based on superabsorbent polymers developed on Faculty of Chemistry, Brno University of Technology, have been used together with commercial preparation – potassium lignohumate kindly provided by co-working commercial subject – Amagro s.r.o. The main aim was the application of lignohumate directly on plants through root system. Results of these experiments should confirm the positive effect on plant growth as well as their positive development. Results obtained from transport/diffusion experiments confirm that the penetration of active compounds (lignohumate) is more efficient in comparison with adaxial cuticles. The kinetics of lignohumate transport is faster for abaxial cuticles. From superabsorbent experiments it is obvious that these play significant role in growth and development of plant and simultaneously positively contribute to creation of suitable conditions for proper microbiological and bacterial activity, which is essential for health soil.
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Transport of Biomedical Active Compounds Through Porous Membranes
Vašíčková, Kateřina ; Smilková, Marcela (referee) ; Smilek, Jiří (advisor)
This bachelor thesis deals with a study of transport of biomedical active compounds through porous membranes. The main goal is to optimize a penetration method of micellar solutions with a solubilized dye and subsequently with solubilized drug. Cetyltrimethylammonium bromide is chosen as a surfactant and a nile red dye is used as a diffusion and fluorescence probe. Selected active compound is a nonsteroidal anti-inflammatory drug ketoprofen with analgesic and antipyretic effects. The diffusion processes are realized using Franz diffusion cells with polycarbonate membrane with a 2 µm size of poruses. The samples are withdrawn in a chosen time intervals and afterwards evaluated by a fluorescence correlation spectroscopy. Using this method, it is possible to screen the diffusion in time even in nanomolar concentrations of a fluorescence probe chosen. This thesis provides an overview of nile red behaviour in the micellar solutions of surfactant during diffusion processes. The experiment can be extended using an active compound, for instance using a ketoprofen as it is mentioned above.
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Stability of humic substances
Nováková, Šárka ; Smilková, Marcela (referee) ; Klučáková, Martina (advisor)
This bachelor´s thesis is focused on the study of stability of humic acid. Thesis is divided in two parts, the first part is theoretical. In the theoretical part is dealing with the structure, property and point of humic acid and in the experimental part is dealing with stability of humic acid. The objective of this thesis was to investigate the effect of the extraction agents on stability of humic acid. 1M HCl, 1M MgCl2 and MiliQ water was used like extraction agents. Thermo-oxidative stability was tested trough thermogravimetric analysis (TGA) and differential scanning calorimetry (DSC). Changes of humic acid that occured after extraction were investigated by FT-IR spektrometry and elementary analysis. The results of the measuring were compared with original humic acid.
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Diffusion characterization of hydrogels at microscopic level
Uher, Tadeáš ; Smilková, Marcela (referee) ; Sedláček, Petr (advisor)
This Bachelor’s thesis deals with study of diffusion in gels on microscopic level. The method of fluorescence correlation spectroscopy is used for the study of diffusion and this method is based on monitoring the diffusion coefficients in a confocal volume of studied substance. As fluorescence probe is used organic pigment called Rhodamin 6G and diffusion experiments are realized in hydrogel matrix, whose medium forms thermoreversible linear polycarbohydrate – agarose, with addition of reactive component – biopolymer called sodium polystyrenesulphate in certain concentrations. The purpose of the thesis is to research the impacts of interaction between diffusing pigment and specific type of hydrogel. The change of final diffusion coefficient is observed. It is assumed, that sodium polystyrenesulphate influences the diffusion of fluorophore (Rhodamin 6G) in agarose hydrogel.
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Hydration of biopolymers
Šméralová, Ester ; Smilková, Marcela (referee) ; Klučáková, Martina (advisor)
Presented bachelor's thesis focuses on the study of hydration of selected biopolymers – humic acids, chitosan, hyaluronic acid (low molecular weight and high molecular weight) and dextran. Thermogravimetric analysis TGA is used t determine the original moisture content of the samples. Two calorimetric methods were used for subsequent observations of changes in their chemical and mechanical properties in the presence of water – differential scanning calorimetry DSC and perfusion calorimetry.
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Transport of humic substances through plant cuticle
Smilková, Marcela ; Salaš, Petr (referee) ; Weidlich, Tomáš (referee) ; Klučáková, Martina (advisor)
Doctoral Thesis is aimed on the transport of liquid preparations chemically based on potassium lignohumate through plant cuticles commonly utilized in agricultural applications. Firstly, the thesis deals with optimization and correct mathematical description of diffusion experiments. Transport (diffusion) experiments have been realized in model hydrogel media based on linear polysaccharide – chemically inert agarose. Diffusion experiments have been realized by two independent approaches (diffusion models) – free diffusion of lignohumate in hydrogel and diffusion pair (hydrogel-hydrogel), where one of these was enriched by lignohumate in contrast with the second one. Plant cuticle, as the major barrier on the leaves, isolated from Prunus laurocerasus, was used as porous membrane in diffusion experiments. The main aim of Ph.D. thesis was the characterization of barrier properties of cuticles, which are the most limiting barrier regulating the transport of lignohumate in/out the leaves during foliar fertilization. These experimental problems have been solved by diffusion experiments and by their proper mathematical description, especially by the determination of fundamental diffusion parameters such as effective diffusion coefficients. These parameters have been used for the modelling of concentration profiles in hydrogels and comparison with experimental data. Significant part of thesis is aimed on the determination of physico-chemical properties of plant cuticles and hydrogels matrixes utilized as model diffusion environment. These characteristics are subsequently correlated with transport (diffusion) parameters. Plant cuticles have been isolated from Prunus laurocerasus leaves and then were characterized by relevant instrumentation notably with respect to their structure and penetration through of lignohumate. Hydrogels have been characterized with respect to mechanical (viscoelastic) (rheology), morphological e.g. porosimetry) and structural (scanning electron microscopy) properties. Mentioned properties have direct link to transport processes ongoing in these materials. Next part of doctoral thesis is aimed on the proper and correct interpretation of experimental results obtained from glass-house experiments. During these experiments, hydrogels based on superabsorbent polymers developed on Faculty of Chemistry, Brno University of Technology, have been used together with commercial preparation – potassium lignohumate kindly provided by co-working commercial subject – Amagro s.r.o. The main aim was the application of lignohumate directly on plants through root system. Results of these experiments should confirm the positive effect on plant growth as well as their positive development. Results obtained from transport/diffusion experiments confirm that the penetration of active compounds (lignohumate) is more efficient in comparison with adaxial cuticles. The kinetics of lignohumate transport is faster for abaxial cuticles. From superabsorbent experiments it is obvious that these play significant role in growth and development of plant and simultaneously positively contribute to creation of suitable conditions for proper microbiological and bacterial activity, which is essential for health soil.
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