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1	Metal Oxide-Hierarchical Porous Silica Nanocomposites Prepared by Nanoemulsion Templating and Integrative Synthesis Hessien, Manal 06 November 2014 (has links) Nanoemulsions are templates that have the potential to fill the gap between micellar systems and latex particles in the preparation of porous materials. A nanoemulsion can also be used as a carrier for uploading the desired materials inside the pore formed after the removal of the template. In this research, oil-in-water (O/W) nanoemulsions were prepared by means of a low-energy method based on a phase inversion composition (PIC) technique, using two nonionic surfactants (Tween 80 and Span 80), which can be mixed in order to adjust the hydrophilic-lipophilic balance (HLB). The influence of a number of parameters on the tunability and stability of such nanoemulsions was also studied. The effect of the simultaneous intercrossing of multifactors on droplet size was explored using a process- mixture design, and the size of the nanoemulsion oil droplets was measured by means of dynamic light scattering (DLS). The nanoemulsions were combined with sol-gel method in order to prepare porous silica with a macroporosity in the 50 nm to 400 nm range. The results demonstrate that a precise synergy between the silica source and the nanoemulsions is essential for effective interactions and homogeneous structures. Depending on the nature of such interactions, a variety of materials were observed, from hollow particles to continuous gels. Changing the size of the oil droplet and the volume of the nanoemulsions produced silica with differing pore sizes and varying total pore volumes. The obtained hierarchical porous silica (HPS) were characterized using mercury porosimetry, small angle X-ray scattering (SAXS), nitrogen isotherms, Fourier transform infrared (FTIR) analysis, transmission electron microscopy (TEM), and scanning electron microscopy (SEM). The parallel use of the oil vesicles as containers for the further synthesis of metal oxide is a novel method of internally functionalizing the silica. When hydrophobic metal precursors are dissolved into the oil phase before the preparation of the nanoemulsion, they are confined within the globular cavities of the silica. The thermal treatment applied to the material to burn the organics then leads to the final formation of metal oxide nanoparticles, which are larger than the porosity of the silica matrix but entrapped within the large cavities, producing a "rattle-like" structure. This method was demonstrated through the synthesis of Fe2O3, Fe3O4, and Co3O4 nanoparticles, and the results showed that a rather large amount of metal oxide (up to a 60 wt.% of metal oxide in nanocomposites) be generated while still maintaining the nanometric size observed at lower concentrations. This method allows control of the type of metal oxide, the concentration of the metal oxide, and the pore size, which enables the creation of different types of nanocomposites. Metal oxide hierarchical porous silica (MHPS) nanocomposites were characterized based on nitrogen isotherms, TEM and SEM observations, FTIR analysis, X-ray diffraction (XRD), and Mossbauer spectroscopy. Magnetic measurements were also taken. This new method, using the new templating objects, is a perfect illustration of the concept of "integrative synthesis,??? whereby the combination of building units and reactional mechanisms leads to complex structures as a result of true synergy among the elements during the reaction. In this case, the size of the nanoemulsion and the total water volume both contribute to the generation of distinctive architectures. In addition, the reaction of the metal oxide precursors within the cavities limits the extension of the final crystal size, but the surrounding solid matrix plays a role as well by keeping the particles apart. The final factor is that the reactive materials cannot leak from the silica because of the rattle-like structure, but the reagents can reach those particles through the porosity of the silica framework. Nanoemulsion Nanoemulsion templating Nanoparticle metal oxide Nanocomposites Hierarchical porous silica Porous Silica Hierarchical Porous Silica Integrative Synthesis
2	BINDING, PROTECTION, AND RNA DELIVERY PROPERTIES OF POROUS SILICA NANOPARTICLES IN SPODOPTERA FRUGIPERDA CELLS Nadeau, Emily 01 January 2017 (has links) Traditional methods of pest control are threatened by the development of insecticide resistance, both to traditional insecticides and Bt toxins. Discovery of RNA interference (RNAi) has created opportunities to develop new insect control mechanisms. However, RNAi responses appear to be robust in coleopteran pests, but other orders, e.g. Lepidoptera and Hemiptera, present varied or ineffective RNAi responses. Current delivery strategies for double-stranded RNA (dsRNA) include microinjection, ingestion, and soaking. These approaches have benefits and problems. This study investigates the potential for porous silica nanoparticles (pSNPs) to improve the delivery of dsRNA and induce an RNAi response in Spodoptera frugiperda cells. Initially, the binding conditions of RNA onto porous and nonporous silica nanoparticles was examined, and the movement of RNA on and within pSNPs was observed. That information was then applied to in vitro studies for examining the capacity of silica nanoparticles to protect dsRNA from degradation by nucleases. This work culminated in an in vivo assay for measuring apoptosis when dsRNA is delivered to insect cells by pSNPs. Results of these studies show that silica nanoparticles bind nucleic acids and that dsRNA is mobile, pSNPs protect dsRNA from nuclease degradation, and pSNP/dsRNA complexes can induce apoptosis in lepidopteran insect cells. RNA Interference Porous Silica Nanoparticles Nucleic Acid Binding Nuclease Protection Insect Cells Agriculture Engineering Entomology
3	Structural Characterisation of Hierarchically Porous Silica: Monolith by NMR Cryo-porometry and -diffusometry Hwang, Seungtaik, Valiullin, Rustem, Haase, Jürgen, Smarsly, Bernd M., Bunde, Armin, Kärger, Jörg 11 September 2018 (has links) A systematic NMR cryo-porometry and -diffusometry study using nitrobenzene as a probe liquid is carried out in order to characterise pore structures of hierarchically-organised porous silica monolith possessing mesopores along with a 3D bicontinuous macropore network. The result obtained from NMR cryoporometry shows the presence of a relatively wide mesopore size distribution of 10-35 nm. Furthermore, NMR cryodiffusometry indicates that whilst the mesopores are highly tortuous (Tmeso ≈6), they have little influence on the overall tortuosity of the material (Tmacro ≈1.5), which is largely dominated by the macropores (Toverall ≈1.7).
4	OPTICAL MEASUREMENT OF ENVIRONMENTAL URANIUM USING POROUS SILICA MATERIALS Chen, Chien-Cheng 17 June 2010 (has links) The focus of this research is on the optical measurement of uranyl in a solid matrix using fluorescence spectroscopy. Nanoporous silica-based materials were used to extract uranyl from contaminated soil and to enhance the fluorescence intensity and lifetime. The fluorescence lifetime and intensity of uranyl ions adsorbed on porous silica-based materials of varying pore size was measured as a function of pH and in the presence of fluoride. The feasibility of uranyl fluorescence detection on the top of soil by silica gel is carried out by four types of natural soil. The results show that the uranyl fluorescence intensity can be enhanced by approximately two orders of magnitude by the silica nanoporous matrix from pH 4-12 with the greatest enhancement occurring from pH 4-7. The enhanced fluorescence lifetime can be used in time-gated measurements to help minimize the influence of background environmental fluorophores. The pH and the fluoride variation causes different uranyl speciation and results in a peak shift in the fluorescence spectrum. The mechanism of the uranyl ion on the silica nanoporous matrix was studied through 15 different silica materials with different water content ratios and various concentrations of uranium on different silica structures. The result shows that the particle size, pore size, water content and uranyl concentration on silica surfaces are all important factors for optimizing the fluorescence intensity. The spacing between silica materials, either the pore inside materials or the space between particles, causes the variety of uranyl distribution on the material surface and changes the fluorescence performance. Also, X-Ray Photoelectron Spectroscopy (XPS) is used to identify the possible uranyl surface species on silica. The fluorescence emission spectra from silica materials and the XPS results are consistent with the presence of two different uranyl compounds. The specific surface area of silica materials plays an important role on uranyl adsorption mechanism. To further enhance the sensitivity, an optical ball lens was used to preferentially direct the fluorescence signal toward the excitation source in standoff measurements. The application of the ball lens was found to increase the detection distance up to 14 times. Uranium Uranyl Micro porous silica Silica gel Fluorescence Directed fluorescence Fluorescence standoff sensor pH effect Soil Engineering
5	SÃntese de sÃlica mesoporosa de grande Ãrea superficial para o tratamento de efluentes e sua aÃÃo conjunta com CaCO3 e o extrato aquoso da folha da bananeira contendo taninos. / Synthesis of mesopours silica with large surface area for wastewater treatment and its joint action with CaCO3 and the aqueous extract of banana containing tannins. JoÃo Ermeson Mota Felix 05 March 2013 (has links) Este trabalho consiste na sÃntese de sÃlica mesoporosa de grande Ãrea superficial e seu uso para fins de tratamento de efluentes na remoÃÃo de metais tÃxicos e compostos orgÃnicos, alÃm do seu uso conjunto com CaCO3 e o extrato aquoso das folhas da planta Musa spp (Bananeira) que provavelmente contem taninos. Existem diversos trabalhos sobre a utilizaÃÃo de sÃlica mesoporosa, de taninos vegetais e do carbonato de cÃlcio, que possuem eficiÃncia na remoÃÃo de metais tÃxicos e de compostos orgÃnicos de corpos hÃdricos e efluentes. A sÃlica Ã um polÃmero inorgÃnico de formula mÃnima SiO2, onde muitos estudos utilizando sÃlica mostram sua eficiÃncia na remoÃÃo da grande maioria dos contaminantes das Ãguas por adsorÃÃo e/ou precipitaÃÃo, sendo esses contaminantes orgÃnicos ou inorgÃnicos e a sÃlica ainda podendo ser utilizada diversas vezes apÃs sua purificaÃÃo. Os taninos sÃo polihidroxifenois de origem vegetal (com massa entre 500 e 3000 g/mol) e os CaCO3 Ã um minÃrio com os mais diversos usos. Assim como os taninos, a utilizaÃÃo de carbonato de cÃlcio para o tratamento de efluentes jÃ se mostrou ser um mÃtodo simples e eficiente. Como amostragem para os testes de remoÃÃo de metais utilizando os compostos isoladamente e depois em conjunto foi utilizada uma soluÃÃo padrÃo dos sais de metais tÃxicos do 1Â e do 3Â grupos analÃticos, contendo aos metais de transiÃÃo da tabela periÃdica e o Al3+, que sÃo os grupos analÃticos de concentraÃÃo conhecida (1Â grupo: Ag+, Pb2+, Hg22+; 3Â grupos: Al3+, Cr2+, Fe2+, Mn2+, Zn2+, Co2+ e Ni2+); onde foram feitos os testes de eficiÃncia e as adiÃÃes dos compostos para retirada dos contaminantes. Ambos os testes de eficiÃncia e de adiÃÃo mostraram retirar boa parte de micro poluentes orgÃnicos e inorgÃnicos, sendo a concentraÃÃo de compostos orgÃnicos medidos pela DQO diminuÃdos a nÃveis abaixo de 5 mg/L e metais como Al3+, Fe2+ e Pb2+ foram removidos da soluÃÃo com eficiÃncia de 95% em relaÃÃo a concentraÃÃo inicial. / This work consists in the synthesis of mesoporous silica of high surface area and its use for wastewater treatment in the removal of toxic metals and organic compounds, and their use together with CaCO3 and aqueous extract of the leaves of the plant Musa spp (Banana) that probably contains tannins. There are several studies on the use of mesoporous silica, vegetable tannin and calcium carbonate, which have efficiency in the removal of toxic metals and organic compounds of bodies of water and wastewater. Silica is an inorganic polymer of formula minimum SiO2, with many studies using silica show its efficiency in removing the majority of contaminants from water by adsorption and / or precipitation with organic or inorganic contaminants such and the silica may still be used several times after its purification. The tannins are polihidroxifenois of plant origin (with mass between 500 and 3000 g / mol) and CaCO3 is a mineral with many uses. As tannins, the use of calcium carbonate to sewage treatment has proved to be a simple and efficient method. As a sample for testing for metal removal using the compounds separately and then together we used a standard solution of the salts of toxic metals of the 1st and 3rd groups analytical containing the transition metals of the periodic table and Al3+, which groups are Analytical known concentration (1st group: Ag+, Pb2+ HG22+; 3rd group: Al3+, Cr2+, Fe2+, Mn2+, Zn2+, Co2+ and Ni2+), where the tests were done and efficiency additions of compounds to remove the contaminants. Both tests of efficiency and plus shown remove much of micro organic and inorganic pollutants, and the concentration of organic compounds measured by COD reduced to levels below 5 mg / l and metals such as Al3+, Fe2+ and Pb2+ were removed from the solution 95% efficiency compared to the initial concentration. Carbonato de cÃlcio Taninos banana SÃlica porosa Metais - toxicologia Calcium carbonate Tannins Banana Porous Silica Metals - Toxicology. QUIMICA INORGANICA
6	Design, Synthesis and Characterization of Porous Silica Nanoparticles and Application in Intracellular Drug Delivery Munusamy, Prabhakaran 04 August 2010 (has links) Nanoparticle mediated drug delivery approaches provide potential opportunities for targeting and killing of intracellular bacteria. Among them, the porous silica nanoparticles deserve special attention due to their multifunctional properties such as high drug loading, controlled drug release and targeting of organs/cells. A review of the functional requirements of an ideal drug delivery system is provided. A general comparison between different drug delivery carriers and key issues to be addressed for intracellular drug delivery is discussed. Acid catalyzed and acid-base catalyzed, sol-gel derived, silica xerogel systems were investigated for sustained release of an aminoglycosides antimicrobial against salmonella infection in a mouse model. The release of gentamicin from the inner hollow part of the carrier is delayed. Further, the higher porosity of the acid–base catalyzed silica xerogel allows for high drug loading compared to the acid catalyzed silica xerogel system. Efficacy of these particles in killing intracellular bacteria (salmonella) was determined by administering three doses of porous silica loaded gentamicin. This proved to be useful in reducing the salmonella in the liver and spleen of infected mice. Furthermore, the presence of silanol groups provides the ability to functionalize the silica xerogel system with organic groups, poly (ethylene glycol) (PEG), to further increase the hydrophilicity of the silica xerogel matrix and to modify the drug release properties. Increase in the hydrophilicity of the matrix allows for faster drug release rate. In order to facilitate controlled drug release, magnetic porous silica xerogels were fabricated by incorporating iron particles within the porous silica. The particles were fabricated using an acid-base catalyzed sol-gel technique. The in-vitro drug release studies confirm that the release rate can be changed by the magnetic field "ON-OFF" mechanism. This novel drug release methodology combined with the property of high drug loading capacity proves to be influential in treating salmonella intracellular bacteria. The potential application of any drug delivery carrier relies on the ability to deliver the requisite drug without adversely affecting the cells over the long term. We have developed silica/calcium nanocomposites and evaluated their solubility behavior. The solubility of particles was characterized by particle size measurements for different periods of time. It was found that the solubility behaviour of the silica/calcium particles was dependent on their calcium content. The results obtained demonstrate the potential to use mesoporous silica/calcium nano-composites for drug delivery applications. The significant contribution of this research to drug delivery technology is on design and development of the novel porous core-shell silica nano-structures. This new core-shell nano-structure combines all the above mentioned properties (high drug loading, magnetic field controlled drug release, and solubility). The main aim of preparing these porous core-shell particles is to have a control over the solubility and drug release property, which is a significant phenomenon, which has not been achieved in any other drug delivery systems. The shell layer acts as a capping agent which dissolves at a controllable rate. The rate at which the shell layer dissolves depends on the composition of the particles. This shell prevents the drug "leakage" from the particles before reaching the target site. The core layer drug loading and release rate was modified by application of a magnetic field. Additionally, inclusion of the calcium ions in the core layer destabilizes the silica network and allows the particles to dissolve at an appropriate rate (which can be controlled by the concentration of the calcium ions). / Ph. D. sol-gel porous silica nanoparticles solubility bio-degradability magnetic properties controlled drug delivery template surfactants intracellular pathogens
7	Design & Fabrication of Microfluidic DNA Extraction Device for Water Quality Monitoring Dang, Bo 10 1900 (has links) <p>Continuous monitoring of pathogens that may be present in water is one of the key preventive measures that can be used in rural areas of developed countries and developing countries to reduce chances of the water borne diseases outbreak. Off-site testing of microbiological contamination of water is conventionally done for monitoring water quality. However, such a process is time consuming and involves using a variety of hazardous reagents. To address these issues, a portable device for rapid detection of unsafe water is needed.</p> <p>One of the key components in this system is to extract DNA from the pathogens. The primary consideration for DNA extraction is to separate DNA from proteins and other cell debris in the lysate solution. The pure population of DNA molecules are then sent downstream for subsequent processing such as real-time PCR (Polymerase Chain Reaction) and BioFET sensors for further identification and analysis.</p> <p>The focus of the thesis will be on the fabrication of a microfluidic DNA extraction system that can achieve high DNA extraction efficiency and a good repeatability. It can also be easily automated, and integrated with other components of the DNA analysis system. The high surface-to-volume macro/mesoporous silica DNA binding column was synthesized using sol-gel silica technology and triblock copolymer F127 was added to form a crack-free mesoporous silica network. Furthermore, a monodispersed polystyrene microspheres soft-template was assembled using a simple but novel technique that employs controlled suction to enhance self-assembly into a periodically patterned structure in the extraction chamber/chambers. In combination of heat annealing treatment of this assembled polystyrene template, one can easily control the size of the macropores in the final macro/mesoporous silica structure to allow a lower pressure resistance for DNA sample flow at elution stage. The final macro/mesoporous silica structure synthesized using heat annealing temperature of 115<sup>o</sup>C for 10 minutes was determined to have a porosity of 83.6%. Mesopores of this silica monolith was determined by BET test to be 3.65 nm and the macroporous ranging from 0.5μm to 0.86μm were observed. In addition, the fabrication of porous silica monolith can be easily integrated with the microfluidic system for achieving DNA extraction purposes</p> / Master of Applied Science (MASc) DNA extraction DNA purification water monitoring microfluidic polystyrene self-assembly Biotechnology Cell and Developmental Biology Chemical Engineering Materials Science and Engineering Mechanical Engineering Microbiology Nanoscience and Nanotechnology Public Health

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