Global ETD Search

11	Charakterizace vybraných polyelektrolytových komplexů metodami strukturní a termické analýzy / Characterization of polyelectrolyte complexes using structural and thermal analysis Řiháčková, Barbora January 2016 (has links) This master thesis deals with study of chitosan-lignohumate, chitosan-polystyrenesulfonate, chitosan-alginate and chitosan-carrageenan polyelectrolyte complexes. The work was motivated by research of finding suitable alternative substance for lignohumate. The molecular weights of substances were characterized using SEC-MALLS. A degree and a character of the interactions between polyelectrolyte were studied by isothermal titration calorimetry and dynamic light scattering method. The calorimetric experiments proved that decreasing concentration of samples causes decreasing of heat flow. The best calorimetric measurements were provided by adding chitosan into polymer solution. The interactions between chitosan and polyanions and influence of mixing order were proved also by measuring intensity of zeta potential, Z-average of particle size and turbidity. New chitosan-based materials have a big potential in agriculture and medicine.
12	Využití metod rozptylu světla při studiu tvorby polyelektrolytových komplexů v systému biopolymer-tenzid / Light Scattering Techniques in the Study on Formation of Polyelectrolyte Complexes in the System Biopolymer-Surfactant Valečková, Vendula January 2017 (has links) This master thesis is dealing with the use of light scattering techniques in the study on formation of polyelectrolyte complexes in the system biopolymer-surfactant. Sodium hyaluronate was chosen as biopolymer and cetyltrimethylammonium bromide and karbethopendecinium bromide were selected as surfactants. The first precipitation experiments were performed to determine the optimal concentration range of surfactants for subsequent titration measurements performed on Zetasizer Nano ZS and for SEC-MALS analysis. The key parameters obtained from these measurements were the values of critical aggregation concentrations in hyaluronate-surfactant systems. It was found out that the increasing molecular weight of hyaluronan in these systems is causing reduction of obtained values of critical aggregation concentrations. Changes of Z-average particle size, zeta potential, polydispersity index, conformation plot, radius of gyration and molecular weight in the hyaluronan-surfactant system were monitored during experiments.
13	Self-assembly and functionality of polymer bottle brushes on surfaces Raguzin, Ivan 13 April 2015 (has links) In the past decade there has been a growing interest in one-dimensional (1D) nanostructures, such as nanowires, nanotubes and nanorods, owing to their size-dependent optical and electronic properties and their potential application as building blocks, interconnects and functional components for assembling nanodevices. One of the ways to obtain such architectures is a template-directed synthesis which is practically a straightforward route to 1D nanostructures. In this approach, the template simply serves as a scaffold, within (or around) which a different material is generated in situ and shaped into a nanostructure with its morphology complementary to that of the template. It is generally accepted that template-directed synthesis provides a simple, high-throughput, and cost-effective procedure that also allows the complex topology present on the surface of a template to be duplicated in a single step. In the current work, utilization of the molecular bottle brushes as templates is proposed for the fabrication of conductive nanorods. Their non-spherical macromolecular geometries and lengths up to a few hundred nanometers allow the application of these structures in nanowire synthesis. The variety of molecular bottle brush architectures and their composition enables the adjustment of appropriate conditions for the preparation of conductive materials. Moreover, the ability of the brushes to assemble on a surface under certain conditions provides their usage as building blocks for the preparation of complex conductive networks. Here, the preparation, characterization, and applications of molecular bottle brushes are discussed. Two main goals were pursued. First, to deepen the knowledge in the synthesis of molecular bottle brushes, and to investigate their behavior on the surface. Second, to explore the application of the brushes as templates or building blocks for the formation of conductive nanowires. For the purpose, new ways of molecular brush synthesis by using the “grafting to” approach had to be developed. It was found that the reaction of nucleophilic addition based on pentofluorophenol chemistry and a coupling “click chemistry” reaction can be used to fabricate molecular brushes. Both methods showed efficient results and demonstrated high reactivity of the backbone with the end groups of the side chains. The “click chemistry” approach, however, demonstrated better results considering higher thicknesses of the brushes and, therefore, higher grafting density of the side chains. The “grafting to” together with the “grafting from” methods are very powerful synthetic tools, which can be used in the fabrication of any desired molecular bottle brush architectures. Additionally, complexation of oppositely charged bottle polymer brushes at a single-molecule level using AFM and CryoTEM was experimentally investigated. It was found that polyelectrolyte complexes have “scrambled-egg” morphology, where oppositely charged polymer chains are not oriented parallel to each other but cross each other. Furthermore, molecular bottle brushes were used as templates for the preparation of conductive nanowires. Three approaches for their fabrication were tested. It was found that brushes could easily be covered with various conductive materials, for example conductive polymers or metals. It was showed that for very small, tiny objects as molecular bottle brushes, one can use FIB in order to build up electrodes at its ends. The electrodes could be sputtered with an accuracy of 500 nm and further be used in the determination of the conductivity. The molecular bottle brushes covered with palladium showed the resistance of 50 MΩ, which, regarding the size of the brush, corresponds to a conductivity of one single molecule being ~1 S*cm-1. The obtained conductivity data were in good correlation with the data found in literature. We believe that the molecular bottle brushes have high potential applicability for the building of complex conductive networks. Future refinement of the synthetic methods, combined with improvements in structuring and positioning of objects at the nanoscale, could lead to their implementation in the construction of high-performance electronic devices. info:eu-repo/classification/ddc/540 ddc:540
14	Multifunctional Chitosan-based Complexes for Nanomedicine / Complexes multifonctionnel à base de chitosane pour la nanomédecine Wu, Danjun 14 December 2015 (has links) Ce travail est consacré à l'élaboration de nano-complexes polyélectrolytes (CPEs) ayant une stabilité améliorée en milieux physiologiques et à l'exemplification de leur fort potentiel d'application comme système de délivrance de (macro) molécules bioactives. Le chitosane comme polycation a été compléxé avec quatre polyanions naturels ayant différents densités de charges et groupements fonctionnels(-COO- et SO3-) à savoir l'acide hyaluronique (HYA), le chondroïtine sulfate (ChonS), le sulfate de dextrane (DS) et l'héparine (HEP). Les facteurs qui influent sur la formation et les propriétés physico-chimiques des nano-complexes chitosane-HYA ont été étudiés. Ces nanovecteurs perdent leur caractère colloïdal en milieux physiologiques. Pour améliorer leur stabilité dans ces conditions, une stratégie innovante qui implique l'ajout de zinc a été conçue. Cette stratégie de stabilisation a été démontrée comme étant polyvalente et a été étendue aux complexes polyélectrolytes (CPEs) chitosane-ChonS. Même si de cette manière une stabilité à long terme a été observée, cette stratégie reste uniquement applicable aux CPEs cationiques. Pour cette raison, une approche alternative permettant l'amélioration de la stabilité des colloïdes à charges positives ou négatives a été mise en oeuvre en concevant des nano-complexes de type coeur-couronne ternaires composés de polyacides forts c'est-à-dire de DS ou d'HEP associés au chitosane en coeur et un complexe chitosane-HYA en couronne. Tous les nano-complexes stables obtenus peuvent encapsuler le ténofovir, une molécule antirétrovirale et être fonctionnalisés par des IgAs de ciblage. En in vitro, ces nanovecteurs montrent une inhibition de l'infection des PBMC par le virus VIH-1 supérieure à l'antirétrovirale seule / This work is devoted to the elaboration of nano-polyelectrolyte complexes (PECs) systems with improved stability in physiological media and to the establishment of their high potential of applications as bioactive (macro) molecule delivery systems. Chitosan as polycation were complexed with four natural polyanions of different charged groups and densities (-COO- and SO3 - as negative charges), namely hyaluronan (HYA), chondroitin sulfate (ChonS), dextran sulfate (DS) and heparin (HEP). The factors impacting the formation and physical-chemical properties of chitosan-HYA nanocomplexes were investigated. However, these nanovectors lost their colloidal character in physiological media. To improve their colloidal stability in physiological conditions, an innovative stabilization strategy was designed, involving zinc ion. This stabilization strategy proved versatile and was extended to chitosan-ChonS PECs. Though a long-term stability was achieved, this strategy was only applicable to cationic PECs. Therefore, an alternate approach enabled the improvement of the colloidal stability in physiological media of both positive and negative colloids by designing core-shell ternary polyelectrolyte nanocomplexes composed of strong polyacid (DS or HEP)-chitosan PECs as core and a chitosan-HYA complex as shell. Furthermore, all of the stabilized nanocomplexes allowed the encapsulation of active molecules anti-retroviral drug tenofovir and surface functionalization with targeting IgAs. In vitro, these nanovectors exhibited an inhibition of infection of PBMCs by HIV-1 virus which could be superior to the free drug Chitosane Acide Hyaluronique Chondroïtine Sulfate Héparine Sulfate de dextrane Complexes Polyélectrolytes Stabilisation Conditions physiologiques Chitosan Hyaluronan Chondroitin sulfate Heparin Dextran sulfate Polyelectrolyte Complexes Stabilization Physiological conditions 620.115
15	Self-assembled carrageenan/protamine polyelectrolyte nanoplexes-Investigation of critical parameters governing their formation and characteristics Dul, M., Paluch, Krzysztof J., Kelly, H., Healy, A.M., Sasse, A., Tajber, L. 02 July 2015 (has links) Yes / The aim of this work was to investigate the feasibility of cross-linker free polyelectrolyte complex formation at the nanoscale between carrageenan (CAR) and protamine (PROT). The properties of CAR/PROT nanoparticles (NPs) were dependent on the carrageenan type: kappa (KC), iota (IC) and lambda (LC), concentration of components, addition of divalent cations, weight mixing ratio (WMR) of constituents and mode of component addition. In the case of 0.1% w/v solutions, IC-based NPs had the smallest particle sizes (100-150nm) and low polydispersity indices (0.1-0.4). A decrease in the solution concentration from 0.1% to 0.05% w/v enabled the formation of KC/PROT NPs. All carrageenans exhibited the ability to form NPs with surface charge ranging from -190 to 40mV. The inclusion of divalent cations caused an increase in the particle size and zeta potential. Infrared analysis confirmed the presence of a complex between CAR and PROT and showed that IC chains undergo structural changes when forming NPs. Colloidal stability of NPs was related to the initial surface charge of particles and was time- and pH-dependent. IC was found to be the most suitable type of CAR when forming nanoplexes with PROT. Calcium Carrageenan Electrolytes Ions Microscopy Nanoparticles Particle size Protamines Spectroscopy Fourier transform infrared Zinc Dynamic light scattering Infrared spectroscopy Polyelectrolyte complexes
16	Aqueous solutions of complexes formed by model polyelectrolytes of opposite charges / Solutions aqueuses de complexes formés par des polyélectrolytes modèles de charge opposée Konko, Iuliia 09 December 2015 (has links) Cette thèse présente une étude des solutions aqueuses de trois complexes de polyélectrolytes (PECs) modèles. Les PECs résultent de la complexation de deux polyélectrolytes linéaires de charge opposée: un polycation (le PDADMA) et trois polyanions de longueur de persistance non électrostatique distinctes: le polystyrene sulfoné (PSS), le poly(α-méthyl styrène sulfoné) (PαMSS) et l’acide hyaluronique (HA). En plus de l’influence de la rigidité intrinsèque des polyanions sur la formation et la structure des PECs, les effets de la force ionique et de la méthode de préparation des solutions aqueuses de PECs ainsi que l’influence de la concentration des solutions binaires de polyélectrolytes initiales ont également été abordés. Nous suggérons que le processus de complexation entre polycations et polyanions en régimes semidilué et concentré est analogue à une gélification. Il y a toutefois une différence entre les deux complexes qui est reliée à la différence de rigidité intrinsèque. / This PhD thesis presents a study of the aqueous solutions of three model polyelectrolyte complexes (PECs). PECs were formed between hydrophilic and highly charged linear macrocations of poly(diallyldimethyl ammonium) (PDADMA) and linear macroanions of distinct intrinsic persistence lengths: sulfonated polystyrene (PSS), sulfonated poly(α-methyl styrene) (PαMSS) and hyaluronate (HA). In addition to the effect of the macroion stiffness on the PEC formation and structure, those of the ionic strength and the way of preparing the PEC aqueous solutions as well as that of the concentration regimes of the initial PE aqueous solutions were also tackled. We suggest the complexation between macrocations and macroanions in the semidilute and concentrated regimes can be described as a universal gelation process. A difference between PDADMA-PSS and PDADMA-HA complexes is related to the primary self-assembling process and is associated with the distinct structural models for PECs. Complexes des polyélectrolytes Solutions des polyélectrolytes Rigidité intrinsèque Diffusion de rayons X aux petites angles Diffusion de neutrons aux petites angles Polyelectrolyte complexes Polyelectrolyte solutions Intrinsic stiffness Small angle X-ray scattering Small angle neutron scattering 541.3
17	Production and characterisation of self-crosslinked chitosan-carrageenan polyelectrolyte complexes Al-Zebari, Nawar January 2017 (has links) Macromolecular biomaterials often require covalent crosslinking to achieve adequate stability and mechanical strength for their given application. However, the use of auxiliary chemicals may be associated with long-term toxicity in the body. Oppositely-charged polyelectrolytes (PEs) have the advantage that they can self-crosslink electrostatically and those derived from marine organisms are an inexpensive alternative to glycosaminoglycans present in the extracellular matrix of human tissues. A range of different combinations of PEs and preparation conditions have been reported in the literature. However, although there has been some work on complex formation between chitosan (CS) and carrageenan (CRG), much of the work undertaken has ignored the effect of pH on the consequent physicochemical properties of self-crosslinked polyelectrolyte complex (PEC) gels, films and scaffolds. Chitosan is a positively-charged polysaccharide with NH3+ side groups derived from shrimp shells and, carrageenan is a negatively-charged polysaccharide with OSO3- side groups derived from red seaweed. These abundant polysaccharides possess advantageous properties such as biodegradability and low toxicity. However, at present, there is no clear consensus on the cell binding properties of CS and CRG or CS-CRG PEC materials. The aim of this study was to explore the properties of crosslinker-free PEC gels, solvent-cast PEC films and freeze-dried PEC scaffolds based on CS and CRG precursors for medical applications. The objective was to characterise the effect of pH of the production conditions on the physicochemical and biological properties of CS-CRG PECs. Experimental work focused on the interaction between PEs, the composition of PECs, the rheological properties of PEC gels and the mechanical properties of PEC films and scaffolds. In addition, cell and protein attachment to the PEC films was assessed to determine their interactions in a biological environment. For biomedical applications, these materials should ideally be stable when produced such that they can be processed to form either a film or a scaffold and have mechanical properties comparable to those of collagenous soft tissues. FTIR was used to confirm PEC formation. Zeta potential measurements indicated that the PECs produced at pH 2-6 had a high strength of electrostatic interaction with the highest occurring at pH 4-5. This resulted in stronger intra-crosslinking in the PEC gels which led to the formation of higher yield, solid content, viscosity and fibre content in PEC gels. The weaker interaction at pH 7-12 resulted in higher levels of CS incorporated into the complex and the formation of inter-crosslinking through entanglements between PEC units. This resulted in the production of strong and stiff PEC films and scaffolds appropriate for soft tissue implants. The PECs prepared at pH 7.4 and 9 also exhibited low swelling and mass loss, which was thought to be due to the high CS content and entanglements. From the range of samples tested, the PECs produced at pH 7.4 appeared to show the optimum combination of yield, stability and homogeneity for soft tissue implants. Biological studies were performed on CS, CRG and PECs prepared at pH 3, 5, 7.4 and 9. All of the PE and PEC films were found to be non-cytotoxic. When the response of three different cell types and a high binding affinity protein (tropoelastin) was evaluated; it was found that the CS-CRG PEC films displayed anti-adhesive properties. Based on these experimental observations and previous studies, a mechanistic model of the anti-adhesive behaviour of PEC surfaces was proposed. It was therefore concluded that the CS-CRG PECs produced might be suitable for non-biofouling applications. 610.28
18	Studium interakcí biopolymer - tenzid pomocí mikrokalorimetrie a metod rozptylu světla / Microcalorimetric and Light Scattering Methods in the Study of Interactions in Biopolymer - Surfactant System Šojdrová, Kamila January 2018 (has links) Biopolymer surfactant systems have been studied by using different physico chemical methods. As the biopolymer, it was chosen high (1400–1600 kDa), medium (250–450 kDa) and low (8–15 kDa) molecular weight sodium hyaluronate. Two cationic surfactants – cetyltrimethylammonium bromide (CTAB) and carbethopendecinium bromide (Septonex) were selected to provide polyelectrolyte complexes with oppositely charged hyaluronan. The critical aggregation concentration of the surfactant in the system was monitored by dynamic light scattering (Zetasizer Nano ZS). SEC-MALS method was used for the description of the conformation of sodium hyaluronate of different molecular weights and polyelectrolytes complexes hyaluronan surfactant after reaching the aggregation point. Isothermal titration calorimetry (ITC) was used to determine the critical aggregation concentration of the surfactant by monitoring the thermal changes accompanying the aggregation of the system. It was found out that the increasing molecular weight of hyaluronan in these systems decreases the critical aggregation concentrations and conversely.
19	Complexes ADN/polycation en solution et aux interfaces en tant que vecteurs de transfection non viraux de pointe / DNA/polycation complexes in bulk and at interfaces as advanced non-viral transfection vectors Sergeeva, Yulia 25 June 2013 (has links) Ma thèse a porté sur des complexes de polyélectrolytes en solution et en films LbL pour la transfection de cellules et le contrôle des interactions cellule-surface. Il est possible de doser un agent de transfection et de l'ADN plasmidique dans des films LbL en ajustant le nombre de couches. Les efficacités de transfection avec différentes lignées cellulaires ont été au moins aussi bonnes que celles rapportées dans la littérature, mais sont restées globalement faibles. Différents nanobags ont également été systématiquement testés menant à un protocole de transfection très efficace avec une faible cytotoxicité pour des fibroblastes humains qui sont difficiles à transfecter. Nous avons pu identifier les architectures LbL qui permettent de contrôler l'adhésion cellulaire même en présence de sérum. Cela nous a permis d'introduire une nouvelle technique pour le suivi in situ de la transfection par QCM-D en suivant la mobilité du cytosquelette qui sera poursuivie dans un futur projet. / My PhD work was focused on polyelectrolyte complexes in bulk and in LbL-films for cell transfection and for controlling cell-surface interactions. It is possible to dose transfection agent and plasmid DNA in LbL-films by adjusting the number of layers. Transfection efficiencies with different cell lines were at least as good as reported in the literature, but remained overall weak. Different nanobags were also tested systematically leading to a highly efficient transfection protocol with low cytotoxicity for human fibroblasts which are difficult to transfect. We were able to identify multilayer architectures that allow to control cell adhesion even in the presence of serum. This allowed us also to introduce a new technique for the in-situ monitoring of transfection by QCM-D through monitoring cytoskeleton mobility which will be further pursued in a future research project. Complexes de polyelectrolytes Interactions cellules-materiaux Films minces Assemblage couche-par-couche Transfection Adsorption des proteins Adhesion cellulaire Lignée cellulaire humaine primaire Polyelectrolyte complexes Cell-surface interactions Thin films Layer-by-layer assembly Transfection Protein adsorption Cellular adhesion Primary human cells 660.29 660.65

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