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21	Produção de microgéis de goma gelana em dispositivos de microfluídica / Production of gellan gum microgels in microfluidic devices Costa, Ana Letícia Rodrigues, 1990- 27 August 2018 (has links) Orientador: Rosiane Lopes da Cunha / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia de Alimentos / Made available in DSpace on 2018-08-27T01:07:13Z (GMT). No. of bitstreams: 1 Costa_AnaLeticiaRodrigues_M.pdf: 3081485 bytes, checksum: 44ad03cd2e14d1ef00c3251b254983eb (MD5) Previous issue date: 2015 / Resumo: A técnica de emulsificação em dispositivos de microfluídica é utilizada para a produção de gotas de diâmetro reduzido e distribuição de tamanho monodispersa. A gelificação da fase dispersa de emulsões água em óleo pode levar à formação de microgéis com elevado potencial para encapsulação de compostos ativos. Do ponto de vista tecnológico, a utilização de partículas de tamanho reduzido permite entrega mais fácil e liberação do bioativo de forma mais eficiente no local alvo. Este trabalho teve como objetivo estudar o processo de formação de microgéis de goma gelana em dispositivos de microfluídica utilizando a técnica de focalização hidrodinâmica. Foram avaliadas as concentrações da goma gelana de 0,5 a 0,7% (m/m) e do agente gelificante acetato de cálcio nas concentrações de 0,5 e 2,0% (m/m) para formação dos microgéis. Na primeira etapa, emulsões simples água em óleo, sendo a fase dispersa constituída de água ou dispersões aquosas de goma gelana e fase contínua constituída por uma mistura composta por óleo de soja e o emulsificante polirricinoleato de poliglicerol (PGPR), foram avaliadas quanto ao regime de formação de gotas em diferentes vazões das fases e razões entre as vazões das fases dispersa e contínua. Também foram determinadas as velocidades reais das fases dentro dos dispositivos de microfluídica e os números adimensionais de Reynolds, Capilar e Weber que descrevem o escoamento dos fluidos no microcanais. Com o controle da condição de processo, vazão de entrada das fases dispersa e contínua, foi possível observar as variações no regime de formação de gotas, que variou desde o gotejamento até o jateamento. Em geral, todas as vazões calculadas (reais) das fases foram menores do que aquelas aplicadas na bomba, sendo este resultado relacionado às limitações das dimensões dos canais e alta viscosidade das fases. Desta forma, os números de Reynolds, Capilar e de Weber calculados a partir das velocidades reais das fases foram menores quando comparados com os valores obtidos usando as velocidades impostas na bomba. Na etapa seguinte, microgéis de goma gelana foram produzidos nos microcanais e caracterizados pela distribuição de tamanho de gotas e microscopia ótica. Os microgéis possuíam formato regular e esférico e distribuição de tamanho altamente monodispersa. O potencial da utilização de microgéis de goma gelana na encapsulação de compostos ativos foi avaliado adicionando o corante hidrofílico Rhodamina B na fase aquosa. As partículas obtidas na saída do dispositivo possuíam coloração vermelha, referente à boa retenção do corante hidrofílico. Desta forma, conclui-se que os microgéis obtidos pela técnica da microfluídica poderão ser utilizados na encapsulação de compostos hidrofílicos, inclusive aqueles sensíveis à temperatura, como as vitaminas e probióticos, na imobilização de proteínas e enzimas, bem como, na entrega de drogas, pois além de apresentarem baixa polidispersidade na distribuição de tamanho das partículas mostraram elevada capacidade de retenção do corante utilizado para simular o composto ativo de interesse / Abstract: Emulsification in microfluidic devices is used for the production of droplets with reduced diameter and monodisperse particle size distribution. Gelation of the disperse phase of water in oil emulsions leads to formation of microgels with high potential for the encapsulation of active compounds. Small particle size allows more efficient release of the bioactive at the target site. This work aimed to study the production of gellan microgel using microfluidic devices through flow- focusing technique. Gellan gum concentration of 0.6% (w/w) and calcium acetate (gelling agent) in concentrations of 0.5 and 2.0% (w/w) were used for the formation of microgels. In the first step, it was evaluated of the droplets formation regime at different flow rates of the phases and flow rate ratio of the dispersed and continuous phases of water-in-oil emulsions, composed by dispersed phase of water or gellan aqueous solutions and continuous phase constituted of a mixture composed of soybean oil and the emulsifier polyglycerol polyricinoleate (PGPR). The real velocity of the phases within the microfluidic devices and dimensionless numbers of Reynols, Capilar and Weber that describe the flow of fluids in microchannels were also evaluated. By controlling the process conditions and the input flow rate of dispersed and continuous phases, variations in the drop formation regime were observed which varied from dripping to the jetting regime, such variation exerted strong influence on droplet size. In general, the real flow rate (calculated values) was lower than those applied by pump, which was related with limitations of the size of channels and high viscosity of the phases. Reynolds, Capilar and Weber numbers calculated from the real velocity were smaller compared with the values obtained using the speed imposed by pump. In the next step, gellan microgels were produced the microchannel and characterized by droplet size distribution and optical microscopy. The microgels exhibit uniform and spherical shape and highly monodisperse distribution size. Potential use as gellan microgels as encapsulating matriz of active compounds was evaluated by adding the hidrophilic dye, Rhodamine B, in the aqueous phase. Results showed a low polydispersity and high hidrophilic compound retention capacity, indicating that microgels obtained by microfluidic technique may be used for the encapsulation of hydrophilic compounds that are sensitive to temperature, such as vitamins, probiotics and immobilization of proteins and enzymes, as well as in drug delivery / Mestrado / Engenharia de Alimentos / Mestra em Engenharia de Alimentos Emulsões Microgéis Microfluidica Encapsulação Emulsions Microgels Microfluidic Encapsulation
22	Osmotic Swelling Behavior of Ionic Microgels Alziyadi, Mohammed Obaid January 2020 (has links) This dissertation studies the thermodynamic and structural properties of aqueous dispersions of ionic microgels ? soft colloidal particles composed of cross-linked polymer gels that swell in a good solvent. Starting from a coarse-grained model of microgel particles, we perform computer simulations and theoretical calculations using two complementary implementations of Poisson- Boltzmann (PB) theory. Within the framework of a cell model, the nonlinear PB equation is exactly solved and used to compute counterion distributions and osmotic pressures. By varying the free energy with respect to microgel size, we obtain exact statistical mechanical relations for the electrostatic component of the single-particle osmotic pressure. Explicit results are presented for equilibrium swelling ratios of charged microcapsules and of charged cylindrical and spherical microgels with fixed charge uniformly distributed over the surface or volume of the particle. Molecular dynamics simulations validate the theoretical findings. In the second method, within a one-component model framework, based on a linear-response approximation for effective electro- static interactions, we develop Monte Carlo (MC) simulations to compute the equilibrium swelling ratio, bulk osmotic pressure, radial distribution function, and static structure factor. Results presented in this dissertation demonstrate that swelling of ionic microgels increases with increasing microgel charge and decreases with increasing concentration of salt and microgels. In addition, results demonstrate that the microion distributions and osmotic pressure determine equilibrium swelling of microgels. Cell model predictions for bulk osmotic pressure agree well with data from MC simulations of the one-component model. The MC simulations also provide access to structural properties and to swelling behavior of microgels in highly concentrated suspensions. Taken together, results obtained in this work provide insight into factors of importance for practical use of microgels as drug delivery systems, in tissue engineering, and for other biomedical applications. microgel suspensions microgels osmotic pressure poisson-boltzmann theory swelling
23	Poly(ethylene glycol) Microgels Formed by a Precipitation Reaction as Drug Delivery Vehicles Thompson, Susan Marie 18 December 2012 (has links) No description available. Biomedical Engineering Poly(ethylene glycol) drug delivery microgels precipitation reaction
24	DEVELOPING SOFT HIERARCHICALLY-STRUCTURED BIOMATERIALS USING PROTEINS AND BACTERIOPHAGES Tian, Lei January 2022 (has links) Bio-interface topography strongly affects the nature and efficiency of interactions with living cells and biological molecules, making hydrogels decorated with micro and nanostructures an attractive choice for a wide range of biomedical applications. Despite the distinct advantages of protein hydrogels, literature in the field has disproportionately focused on synthetic polymers to the point that most methods are inherently incompatible with proteins and heat-sensitive molecules. We report the development of multiple biomolecule-friendly technologies to construct microstructured protein and bacteriophage (bacterial virus) hydrogels. Firstly, ordered and sphericity-controllable microbumps were obtained on the surface of protein hydrogels using polystyrene microporous templates. Addition of protein nanogels resulted in the hierarchical nano-on-micro morphology on the microbumps, exhibiting bacterial repellency 100 times stronger than a flat hydrogel surface. The developed microstructures are therefore especially suitable for antifouling applications. The microstructures created on protein hydrogels paved the way for applying honeycomb template on proteinous bacterial viruses. We developed a high-throughput method to manufacture isolated, homogenous, pure and hybrid phage microgels. The crosslinked phages in each phage-exclusive microgel self-organized and exhibited a highly-aligned nanofibrous texture. Sprays of hybrid microgels loaded with potent virulent phage effectively reduced heavy loads of multidrug resistant Escherichia coli O157:H7 on food products by 6 logs. / Thesis / Doctor of Philosophy (PhD) / Bacteriophages (bacterial viruses), also known as phages, are natural bacteria predators. These viruses act as direct missiles, each phage targeting limited groups of bacteria. In addition, phages are an endless resource for self-propagating nanoparticles that can be used as building blocks for new material. I developed a platform for manufacturing a large quantity of microscale beads made of millions of phages. These micro-beads can be sprayed on fresh produce and meat to remove bacterial contamination (with the added benefit of not affecting taste or smell). I also printed phages on substrates, like an ink. The printed phage ink evolved into a patented technology for designing phage coatings on surfaces with very high surface area, like the small structures on our fingers. This phage coating was successfully used to test the existence of bacteria in liquids. bacteriophage biomaterials microstructures hydrogels microgels food safety wrinkles inkjet printing
25	MICROGEL BASED ADHESIVES FOR WET PAPER STRENGTH WEN, QUAN 04 1900 (has links) <p>The interactions of microgel based adhesives with cellulose were studied by peel test of cellulose laminates and tensile test of handsheets. The objective of this project was to create design rules for microgel based adhesives so as to improve the wet paper strength. Colloidal microgel based adhesives were formed by coating carboxylated poly(Nisopropylacrylamide) (PNIPAM) microgels with polyvinylamine (PVAm). The characterization of the microgel base adhesives were performed by electrophoretic mobilities, dynamic light scattering, and potentiometric titration. The microgel based adhesives were pH sensitive and their swelling behaviour was related to the composition of PVAm in the microgels. The maximum amount of PVAm binding to microgels depends on the location of charges in the microgels and the molecular weight of PVAm. The binding process of PVAm to microgels was monitored by quartz crystal microbalance measurements. It is proposed that the binding of PVAm to microgels is controlled by the rate of initial attachment of PVAm and the rate of reconfiguration of PVAm on the microgels. The microgel based adhesives were laminated between oxidized cellulose films and the wet adhesion of microgel based adhesives with cellulose was studied by a 90° peel test. The wet delamination force was measured as a function of PVAm content, PVAm molecular weight, coverage of adhesives on cellulose films, size of adhesives, stiffness of adhesives and the roughness of cellulose films. The wet adhesion of microgel based adhesives with cellulose increased with PVAm content in the microgels, and decreased with microgel stiffness. The molecular weight of PVAm did not influence the performance of adhesives. The effect of microgel size on wet adhesion with cellulose was related to the roughness of cellulose films. Larger microgels did fill the voids between rough cellulose films to create more contact area with these films resulting in higher wet adhesion. By contrast, for smooth cellulose films, the size of microgels didn’t affect the wet adhesion. Finally, this basic research was extended to a practical situation. The microgel based adhesives were added to unbeaten, bleached softwood pulp to prepare handsheets and their ability to enhance wet paper strength was evaluated by tensile test. The wet paper strength increased with PVAm content of the microgels. For linear PVAm, high molecular weight PVAm was more effective as a wet strength adhesive while for PVAm coated microgels, the molecular weight was not significant for wet paper strength. With the aid of PVAm coating, solid carboxylated polystyrene particles improved the wet paper strength. However the wet strength of paper treated with PVAm coated microgels was larger than that treated with PVAm coated polystyrene by a factor of 2.</p> / Doctor of Philosophy (PhD) microgels polyvinylamine adhesion cellulose peel mechanics Polymer Science Polymer Science
26	Synthèse de microgels biocompatibles, hybrides et stimulables pour des applications cosmétiques / Synthesis of biocompatible, hybrid and multiresponsive microgels for cosmetic applications Boularas, Mohamed 22 May 2015 (has links) Ce travail de thèse porte sur l’élaboration de microgels biocompatibles et multi-stimulables à base de méthacrylate d’oligo(éthylène glycol) et de nanoparticules d’oxyde de fer. Des microgels sensibles au pH, à la température et au champ magnétique ont été élaborés au cours de cette étude via une stratégie multi-étape partant de : 1. la synthèse et la caractérisation de microgels pH- et thermosensibles à base d’oligo(éthylène glycol), 2. l'élaboration de microgels hybrides par imprégnation de nanoparticules magnétiques au sein des microgels d’oligo(éthylène glycol). L’étude de la synthèse des microgels et de leurs propriétés physico-chimiques a permis de mettre en avant l’effet important de la structure interne des microgels sur leurs propriétés de gonflement/contraction. La caractérisation des microgels hybrides a mis en évidence l’importance des fonctions acide carboxylique réparties de manière homogène au sein des microgels, le tout permettant d’encapsuler efficacement et de manière homogène des nanoparticules magnétiques tout en préservant les propriétés colloïdales et thermo-stimulables des microgels hybrides. Enfin des films structurés constitués de multicouches de microgels ont ainsi pu être élaborés via un procédé simple de séchage de dispersion aqueuse de microgels. Une étude prospective des propriétés optique et mécanoélectrique de films auto-assemblés de microgels d’oligo(éthylène glycol) hybride et non hybride par évaporation de solvant a permis de mettre en évidence le rôle positif des groupements ioniques issus des fonctions carboxylates sur le potentiel électrique induit lors de la compression des films. / Smart polymer materials can provide wide range of options to induce advanced functional features and relevant surface properties in one material. This all-in-one concept is of great interest for applications that require several simultaneous treatments such as cosmetic application. Herein, we aim to develop oligo(ethylene glycol)-based biocompatible multiresponsive microgels that could both interact on the skin as smart drug delivery system (DDS) while fulfilling advanced properties such as surface protection, mechanical and optical properties. Specifically, aqueous dispersed microgels responsive to pH, temperature and magnetic field were synthesized via multi-step strategy: 1. The synthesis and characterization of pH- and thermo-responsive oligo(ethylene glycol)-based microgels by precipitation polymerization, 2. The encapsulation of pre-formed magnetic nanoparticles via adsorption of the nanoparticles into the multiresponsive microgels. The effect of the microgel microstructure on their pH- and thermo-responsive properties were highlighted thanks to a rational investigation of the crosslink density and acid-functional units distribution within the microgels. Oligo(ethylene glycol)-based microgels with homogeneous distribution of both acid-functional unit and crosslinker allowed the synthesis of highly pH-and thermo-responsive microgels. The hybrid microgels prepared by straightforward encapsulation of pre-formed magnetic nanoparticles were characterized. The homogeneous microstructure of the initial stimuli-responsive biocompatible microgels plays a crucial role for the design of unique well-defined ethylene glycol-based thermoresponsive hybrid microgels. Thus, robust monodisperse thermoresponsive magnetic microgels were produced, exhibiting both a constant value of the swelling-to-collapse transition temperature and good colloidal stability whatever the NPs content. These smart microgels can spontaneously form a transparent film with perfect arrangement of the microgels by simple solvent evaporation process. The characterization of the optical and mechanoelectrical properties of the self-assembled microgel films were performed. We highlighted that the presence of anionic charges inside the microgels emphasizes the mechanoelectrical effect of the films. Microgels Multi-stimulables Matériaux hybrides Nanoparticules magnetiques Polymerisation Films auto-assemblés Transductions mécanoélectriques Microgels Stimuli-responsive Hybrid materials Magnetic nanoparticles Polymerization Self-assembled films Mechanoelectrical transduction
27	A Study of the Flow of Microgels in Patterned Microchannels Fiddes, Lindsey 30 August 2011 (has links) This work describes the results of experimental study of the flow of soft objects (microgels) through microchannels. This work was carried with the intention of building a fundamental biophysical model for the flow of neutrophil cells in microcirculatory system. In Chapter 1 we give a summary of the literature describing the flow of cells and “model cells” in microchannels. Paramount to this we developed methods to modify microchannels fabricated in poly(dimethyl siloxane) (PDMS). Originally, these microchannels could not be used to mimic biological microenvironments because they are hydrophobic and have rectangular cross-sections. We designed a method to create durable protein coatings in PDMS microchannels, as outlined in Chapter 3. Surface modification of the channels was accomplished by a two-step approach which included (i) the site-specific photografting of a layer of poly(acrylamide) (PAAm) to the PDMS surface and (ii) the bioconjugation of PAAm with the desired protein. This method is compatible with different channel geometries and it exhibits excellent longevity under shear stresses up to 1 dyn/cm. The modification was proven to be successful for various proteins of various molecular weights and does not affect protein activity. The microchannels were further modified by modifying the cross-sections in order to replicate cardiovascular flow conditions. In our work, we transformed the rectangular cross-sections into circular corss-sections. Microchannels were modified by polymerizing a liquid silicone oligomer around a gas stream coaxially introduced into the channel, as outlined in Chapter 3. We demonstrated the ability to control the diameter of circular cross-sections of microchannels. The flow behaviour of microgels in microchannels was studied in a series of experiments aimed at studying microgel flow (i) under electrostatic interactions (Chapter 4), (ii) binding of proteins attached to the microgel and the microchannel (Chapter 5) and (iii) under the conditions of varying channel geometry (Chapter 6). This work overall present’s new methods to study the flow of soft objects such as cells, in the confined geometries of microchannels. Using these methods, variables can be independently probed and analyzed. microgels microchannels shear stress electrostatic interactions receptor-ligand binding protein patterning model cell 0495
28	Propriétés mécaniques et nanotribologiques de monocouches auto-assemblées de microgels de poly(NIPAM) cationique en milieux aqueux Vialar, Pierre 10 1900 (has links) No description available. Hydrogels Microgels Surfaces Nanotribologie pNIPAM Nanotribology
29	Novel Cellulose Nanoparticles for Potential Cosmetic and Pharmaceutical Applications Dhar, Neha January 2010 (has links) Cellulose is one of the most abundant biopolymers found in nature. Cellulose based derivatives have a number of advantages including recyclability, reproducibility, biocompatibility, biodegradability, cost effectiveness and availability in a wide variety of forms. Due to the benefits of cellulose based systems, this research study was aimed at developing novel cellulosic nanoparticles with potential pharmaceutical and personal care applications. Two different cellulosic systems were evaluated, each with its own benefits and proposed applications. The first project involves the synthesis and characterization of polyampholyte nanoparticles composed of chitosan and carboxymethyl cellulose (CMC), a cellulosic ether. EDC carbodiimide chemistry and inverse microemulsion technique was used to produce crosslinked nanoparticles. Chitosan and carboxymethyl cellulose provide amine and carboxylic acid functionality to the nanoparticles thereby making them pH responsive. Chitosan and carboxymethyl cellulose also make the nanoparticles biodegradable and biocompatible, making them suitable candidates for pharmaceutical applications. The synthesis was then extended to chitosan and modified methyl cellulose microgel system. The prime reason for using methyl cellulose was to introduce thermo-responsive characteristics to the microgel system. Methyl cellulose was modified by carboxymethylation to introduce carboxylic acid functionality, and the chitosan-modified methyl cellulose microgel system was found to be pH as well as temperature responsive. Several techniques were used to characterize the two microgel systems, for e.g. potentiometric and conductometric titrations, dynamic light scattering and zeta potential measurements. FTIR along with potentiometric and conductometric titration was used to confirm the carboxymethylation of methyl cellulose. For both systems, polyampholytic behaviour was observed in a pH range of 4-9. The microgels showed swelling at low and high pH values and deswelling at isoelectric point (IEP). Zeta potential values confirmed the presence of positive charges on the microgel at low pH, negative charges at high pH and neutral charge at the IEP. For chitosan-modified methyl cellulose microgel system, temperature dependent behaviour was observed with dynamic light scattering. The second research project involved the study of binding interaction between nanocrystalline cellulose (NCC) and an oppositely charged surfactant tetradecyl trimethyl ammonium bromide (TTAB). NCC is a crystalline form of cellulose obtained from natural sources like wood, cotton or animal sources. These rodlike nanocrystals prepared by acid hydrolysis of native cellulose possess negatively charged surface. The interaction between negatively charged NCC and cationic TTAB surfactant was examined and it was observed that in the presence of TTAB, aqueous suspensions of NCC became unstable and phase separated. A study of this kind is imperative since NCC suspensions are proposed to be used in personal care applications (such as shampoos and conditioners) which also consist of surfactant formulations. Therefore, NCC suspensions would not be useful for applications that employ an oppositely charged surfactant. In order to prevent destabilization, poly (ethylene glycol) methacrylate (PEGMA) chains were grafted on the NCC surface to prevent the phase separation in presence of a cationic surfactant. Grafting was carried out using the free radical approach. The NCC-TTAB polymer surfactant interactions were studied via isothermal titration calorimetry (ITC), surface tensiometry, conductivity measurements, phase separation and zeta potential measurements. The major forces involve in these systems are electrostatic and hydrophobic interactions. ITC and surface tension results confirmed two kinds of interactions: (i) electrostatically driven NCC-TTAB complexes formed in the bulk and at the interface and (ii) hydrophobically driven TTAB micellization on the NCC rods. Conductivity and surface tension results confirmed that the critical micelle concentration of TTAB (CMCTTAB) shifted to higher values in the presence of NCC. Phase separation measurements allowed us to identify the formation of large aggregates or hydrophobic flocs depending on the TTAB concentration. Formation of NCC-TTAB complexes in aqueous solutions was confirmed by a charge reversal from negative to positive charge on the NCC rods. The effect of electrolyte in shielding the negative charges on the NCC was observed from ITC, surface tensiometry and phase separation experiments. Several mechanisms have been proposed to explain the above results. Grafting of PEGMA on the NCC surface was confirmed using FTIR and ITC experiments. In phase separation experiments NCC-g-PEGMA samples showed greater stability in the presence of TTAB compared to unmodified NCC. By comparing ITC and phase separation results, an optimum grafting ratio (PEGMA : NCC) for steric stabilization was also proposed. Polyampholyte microgels Nanocrystalline cellulose Chitosan Methyl cellulose Carboxymethyl cellulose PEGMA-Grafting Chemical Engineering
30	From soft to hard sphere behavior: the role of single particle elasticity over the phase behavior of microgel suspensions Lietor-Santos, Juan-Jose 11 November 2010 (has links) The goal of this thesis is to study the role of single particle elasticity in the overall behavior of particulate systems. For this purpose, we use microgel particles, which are crosslinked polymer networks immersed in a solvent. In these systems, the amount of cross-linker determines their elasticity and ultimately the stiffness of the particle. For a system of hard spheres, the phase behavior is solely determined by the volume fraction occupied by the particles. Based on the volume fraction, liquid, crystal and glassy phases are observed. Interestingly, microgel particles display a richer and fascinating set of different behaviors depending on the particle stiffness. Previous results obtained in our group show that for highly cross-linked microgels, the glass phase disappears and there are only liquid and crystalline phases. By contrast, preliminary measurements indicate that for ultrasoft microgel particles the system does not show any signature of crystalline or glassy phases. The system seems to remain liquid irrespective of volume fractions. In this Thesis, we will address this striking result using light scattering as well as rheology, in order to access both static and dynamic properties in a wide range of length and time scales. In addition, we will also perform additional studies using very stiff microgels and use their swelling capabilities to change the volume fraction. We will use hydrostatic pressure to change the miscibility of the polymer network and thus change the microgel size; the use of this external variable allows fast equilibration times and homogeneous changes throughout the sample. By using neutron scattering techniques, we study the structural and dynamical properties of the system in its different phases involved. Particle stiffness Microgels Hard spheres Soft condensed matter Rheology Neutron scattering Colloids Elasticity Particles

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