The flocculation of charged particles in aqueous solutions by cationic polyelectrolytes

Lee, Shun Yin

January 1991

No description available.

541

Sea water; Silica particles; Polymer

Particle-modified surface plasmon resonance biosensor

Du, Yao

January 2019

Surface plasmon resonance (SPR) biosensors have attracted great attention in scientific research in the past three decades. Extensive studies on the immobilisation of biorecognition elements have been conducted in pursuit of higher sensitivity, but trialled formats have focussed on a thin layer modification next to the plasmon film, which usually requires in situ derivatization. This thesis investigates an 'off-chip' immobilisation strategy for SPR biosensing using silica particles and considers the implications of a particle-modified evanescent field on the signal amplitude and kinetics, for an exemplar affinity binding between immobilised IgG and its anti-IgG complement. Submicron silica particles were synthesized as carriers for the bio-recognition elements. They were then immobilised to form a sub-monolayer on the gold film of an SPR biosensor using two methods: thiolsilane coupling and physical adsorption aided by mechanical pressure. The bio-sensitivity towards an antigen/antibody interaction was lower than an SPR biosensor with an alkanethiolate SAM due to the difference in ligand capacity and position in the evanescent field. The binding kinetics of antigen/antibody pair was found to follow the Langmuir model closely in a continuous flow configuration but was heavily limited by the mass transport from the bulk to the sensor surface in a stop-flow configuration. A packed channel configuration was designed with larger gel particles as ligand carriers, packed on top of a gold film to create a column-modified SPR biosensor. This sensor has comparable bio-sensitivity to the previous sub-monolayer particle-modified systems, but the binding and dissociation of the analyte was heavily dependent on mass transport and binding equilibria across the column. A bi-directional diffusion mechanism was proposed based on a two-compartment mass transport model and the expanded model fitted well with the experimental data. The column-modified sensor was also studied by SPR imaging and analyte band formation was observed and analysed. Using the lateral resolution, a multiplexing particle column configuration was explored, and its potential in distinguishing a multicomponent analyte.

Development of New Polysilsesquioxane Spherical Particles as Stabilized Active Ingredients For Sunscreens

Tolbert, Stephanie Helene

January 2015

Healthy skin is a sign of positive self-worth, attractiveness and vitality. Compromises to this are frequently caused by extended periods of recreation in the sun and in turn exposure to the harmful effects of UV radiation. To maintain strength and integrity, protection of the skin is paramount. This can be achieved by implementing skin-care products which contain sunscreen active ingredients that provide UV protection. Unfortunately, photo-degradation, toxicity, and photo-allergies limit the effectiveness of present day sunscreen ingredients. Currently, this is moderated by physically embedding within inert silica particles, but leaching of the active ingredient can occur, thereby negating protective efforts. Alternatively, this research details the preparation and investigation of bridged silsesquioxane analogues of commercial ingredients which can be chemically grafted to the silica matrix. Studies with bridged salicylate particles detail facile preparation, minimized leaching, and enhanced UV stability over physically encapsulated and pendant salicylate counterparts. In terms of UVB protective ability, the highest maintenance of sun protection factor (SPF) after extended UV exposure was achieved with bridged incorporation, and has been attributed to corollary UV stability. Additionally, bridged salicylate particles can be classified as broad-spectrum, and rate from moderate to good in terms of UVA protective ability. Particles incorporated with a bridged curcuminoid silsesquioxane were also prepared and displayed comparable results. As such, an attractive method for sunscreen isolation and stabilization has been developed to eliminate the problems associated with current sunscreens, all while maintaining the established UV absorbance profiles of the parent compound. To appreciate the technology utilized in this research, a thorough understanding of sol-gel science as it pertains to hybrid organic/silica particles, including methods of organic fragment incorporation and insight on the effect of incorporation method on ingredient leaching and UV stability, is vital. This was afforded by analysis of hybrid fluorescent dansyl particles, prepared by both O/W microemulsion polymerization and a modified Stöber process, which detailed that covalent entrapment of bridged dansyl silsesquioxane is the incorporation method of choice to ensure minimized leaching and enhanced UV stability. As such, use of this method can provide exciting applications in fields where stability and retainment of the embedded ingredient is paramount for efficacy.

silica particles

sol-gel

sunscreens

polysilsesquioxane

Chemistry

Studies on Electrostatic Interactions between Biomolecules and Silica Particles using Time-Resolved Fluorescence Anisotropy

Sui, Jie

January 2005

<p> This thesis focuses on the use of time-resolved fluorescence anisotropy (TRF A) for the analysis of peptide-silica and protein-silica interactions. Previous studies from our group have shown that strong ionic binding of the cationic probe rhodamine 6G (R6G) to the anionic surface of silica particles in water provides a convenient labeling procedure to study both particle growth kinetics and surface modification by time-resolved fluorescence anisotropy (TRF A). The decays for R6G dispersed in diluted Ludox silica sols usually fit to a sum of picosecond and nanosecond decay components, along with a significant residual anisotropy component. The first objective of my work was to assess the nature of the R6G:silica interaction to determine the origin of the nanosecond decay component, and ultimately validate the model used to fit the TRFA data and gain further insight into the physical meaning of the anisotropy decay parameters. Our results show the origin of the nanosecond decay component ( ¢2) is due to the presence of a subpopulation of small nanoparticles in the Ludox sol. </p> <p> With the correct physical model in place, we have been able use TRFA ofR6G in aqueous Ludox to monitor peptide adsorption onto the silica particles in situ. Steady-state anisotropy and TRF A of R6G in Ludox sols were measured to characterize the extent of the ionic binding of the probe to silica particles in the presence of varying levels of tripeptides of varying charge, including Lys-Trp-Lys (KWK), N-acetylated Lys-Trp-Lys (Ac-KWK), Glu-Trp-Glu (EWE) and N-acetylated Glu-Trp-Glu (Ac-EWE). R6G showed significant decreases in anisotropy in the presence of cationic peptides, consistent with the addition of cationic peptides blocking the adsorption of the dye to the silica surface. The study shows that the competitive binding method can be used to assess the binding of various biologically relevant compounds onto silica surfaces, and demonstrates the potential of TRF A for probing peptide: silica and protein: silica interactions. </p> <p> We have also extended the application of TRF A to monitor protein adsorption onto plain and modified silica particles using a recently reported cationic long-lifetime quinolinium dye, CG437, which strongly binds to anionic silica particles through electrostatic interactions. In this case, alterations in the rotational correlation time of Ludox particles resulting from increases in the diameter of the rotating body upon binding of protein to the silica surface were monitored. The study shows that TRFA analysis of long-lived cationic probes such as CG437 can provide an effective method to investigate interactions between proteins and modified silica surfaces, extending the utility of the TRF A method. </p> / Thesis / Master of Science (MSc)

Electrostatic Interactions

Biomolecules

Silica Particles

fluorescence anisotropy

DESIGN AND CHARACTERIZATION OF NAFION®/EX-SITU SILICA NANOCOMPOSITE MEMBRANES: EFFECTS OF PARTICLE SIZE AND SURFACE MODIFICATION

Muriithi, Beatrice Wanjku

January 2009

This dissertation focuses on the preparation of new Nafion®/ ex-situ silica nanocomposites membranes and the impact of particle size of spherical silica particles on the nanocomposites' properties. To achieve acceptable power production, fuel cell polymer membranes are required with good proton conductivity, water retention, thermal and mechanical stability. However, to avoid poisoning of fuel cell electrocatalysts with CO or other fuel contaminants, they must be operated at temperatures (>100 °C). At these temperatures, fuel cell membranes dehydrate resulting in dramatic decreases in proton conductivity or complete failure as membranes crack due to volumetric stress from water loss. Even if fuel cell is kept in a humidified chamber, increasing temperature will eventually shut the cell down as Nafion®'s bicontinuous structure "dissolves" into a single poorly conducting phase at temperatures above the polymer's Tg.This research provides systematic studies of effects of silica particle size on properties of silica-Nafion® nanocomposites. Results of this study include new insights into requirements for reproducible particle syntheses, practical methods for avoiding silica particle floatation during Nafion® nanocomposite membranes preparation, and a summary of the influence of particle size and functionalization on Nafion® membrane properties. Stober particle syntheses showed high sensitive to ammonia concentration and we discovered that literature procedures' variability is likely due to researchers failure to actually measure ammonia concentration in their aqueous base (which can be 50% or more off). Homogeneous nanocomposite membranes, as determined by AFM and SEM, were successfully prepared using more viscous dispersions. It was observed that nanocomposites membranes with small particles (<50 nm) showed significant increases in proton conductivity at temperatures above 80 °C. Surface modification of the silica particles improved the proton conductivity at 80 °C. Enhancement on proton conductivity was more pronounced with small modified particles at temperatures < 80 °C but unmodified particles were better than modified particles at temperatures >80 °C. Small, unmodified particles led to enhanced thermal stability of the Nafion® ionic domain, however, surface modification did not result in any thermal stability enhancement. Contrary to the expected, mechanical properties of the Nafion® were degraded by adding the silica particles, especially with smaller particles (<50nm).

Nafion

Nanocomposite membranes

Polymer electrolyte fuel cell

Silica particles

SILICA AEROGEL-POLYMER NANOCOMPOSITES AND NEW NANOPARTICLE SYNTHESES

Boday, Dylan Joseph

January 2009

Aerogels are extremely high surface area, low density materials with applications including thermal and acoustic insulators, radiation detectors and cometary dust particle traps. However, their low density and aggregate structure makes them extremely fragile and practically impossible to machine or handle without breaking. This has led to the development of aerogel composites with enhanced mechanical properties through the addition of polymers or surface modifiers. To date, attempts to strengthen aerogels have come with significant increases in density and processing time. Here I will describe our search for a solution to these problems with our invention using methyl cyanoacrylate chemical vapor deposition (CVD) to strengthen silica, aminated silica and bridged polysilsesquioxane aerogels. This approach led to a strength improvement of the composites within hours and the strongest composite prepared had a 100x strength improvement over the precursor aerogel. We also developed the first approach to control the molecular weight of the polymers that reinforce silica aerogels using surface-initiated atom transfer radical polymerization (SI-ATRP). Although PMMA reinforcement of silica aerogels improved the mechanical properties, further strength improvements were achieved by cross-linking the grafted PMMA. Additionally, we developed the first silica aerogels reinforced with polyaniline nanofibers that were strong and electrically conductive. Reinforcing silica aerogels with polyaniline allowed them to be used as a sensor for the detection of protonating and deprotonating gaseous species. Finally we developed a new approach for the synthesis of silica and bridged polysilsesquioxane spheres using a surfactant free synthesis. This approach allowed for the first in-situ incorporation of base sensitive functionalities during the sol-gel polymerization.

ATRP

Polyaniline

Silica Aerogel

Silica Particles

sol-gel

Strong Aerogels

Nano-Scale Modified Inorganic/Organic Hybrid Materials as Proton Conductors

Chou, Berryinne

07 April 2006

No description available.

BPSH

silica particles

Silica

Sultone

membrane

Particle

treated silica

INVESTIGATING THE FEASIBILITY OF USING MESOPOROUS SILICA PARTICLES TO DELIVER GLUCOSE DURING ANAEROBIC FERMENTATION

Walz, Megan E.

01 January 2019

The study presented herein investigated a potential low-energy method to separate and concentrate glucose from a lignocellulosic hydrolysate. The motivation for this method was twofold: 1) to provide the fermentation microorganism an optimal glucose concentration and 2) to supply a fermentation media free of inhibitory compounds. Two sizes of porous silica particles (with 7 nm and 2.3 nm pores) were synthesized and their ability to adsorb glucose from solution confirmed. Next, the ability of two different microorganisms, Saccharomyces cerevisiae and Streptococcus bovis, to utilize sugars adsorbed to the porous silica particles was investigated. Both the 7 nm and 2.3 nm pore-size particles were capable of adsorbing glucose from solution. Fermentations with glucose provided adsorbed to nanoparticles were compared to fermentations with glucose dissolved in media. The success of the fermentation was assessed by using high performance liquid chromatography to compare the concentration of fermentation products at harvest time. Results indicated that although the fermentation with soluble glucose produced significantly more end-products, S. bovis demonstrated some ability to metabolize the glucose adsorbed to the 7 nm pore silica particles. No evidence was detected that S. cerevisiae could metabolize glucose adsorbed to silica particles of either pore size.

facilitated diffusion

Streptococcus bovis

Saccharomyces cerevisiae

biomass

hydrolysate

silica particles

Biological Engineering

Development and Characterization of Stationary Phase Gradients for High Performance Liquid Chromatography

Forzano, Anna

01 January 2019

Choosing a stationary phase is the first step in developing a liquid chromatography (LC) separation method, where the selectivity is governed by the differential interactions of the analytes with the stationary and mobile phases. Introducing a gradient in stationary phase functionality allows for tuning of analyte retention, translating to a possible improvement in selectivity and an increase in resolution versus that offered by uniform stationary phases. In this work, C18-silica, phenylbutyl-silica, and phenylbutyl-ammonium opposed continuous stationary phase gradients were fabricated using controlled rate infusion (CRI) on particle packed LC columns. Characterization of the stationary phase was carried out using spectroscopy and LC analysis to relate the ligand density gradient profile to the observed chromatographic parameters. C18-silica gradients were created with a time-dependent acid hydrolysis infusion and demonstrated an increase in resolution when combined with a mobile phase gradient. Phenylbutyl-silica and phenylbutyl-ammonium gradients were produced using an in-situ silanization CRI method. Phenylbutyl-silica gradients were confirmed to be stable and reproducible; however, produced tailing peak shapes. Phenylbutyl-ammonium gradients were utilized to incorporate an ion exchange model into a simulator built by Jeong et al. The phenylbutyl-ammonium gradient was not reproducible but did exhibit an increase in resolution when combined with a mobile phase gradient. Also, the ion exchange model was successfully added within the simulator, with percent differences for retention prediction all under 5 %. This dissertation serves as a proof-of-concept for gradient stationary phases on particle packed LC columns.

Liquid chromatography

silica particles

stationary phase gradients

silane chemistry

Analytical Chemistry

ENCAPSULATION OF FOLIC ACID IN MESOPOROUS SILICA SUPPORTS: A NUTRITIONAL AND TECHNOLOGICAL APPROACH

Pérez Esteve, Edgar

09 December 2015

Tesis por compendio / [EN] The present PhD thesis, entitled "Encapsulation of folic acid in silica porous supports: a nutritional and technological approach", focuses on the development of new smart systems for the controlled delivery of folic acid for nutritional applications. The first part of the thesis shows folic acid encapsulation in polyamines-functionalized silica porous matrices from a nutritional approach. The first part evaluates not only the influence of the loading method and the type of silica support employed (MCM-41, SBA-15, UVM-7 and Hollow Silica) on the efficacy of folic acid encapsulation, but also the influence of the morphology and porous system on the folic acid delivery profile from different supports. Folic acid release studies from different supports with various pH values have demonstrated that the designed systems are capable of smartly modulating the delivery of the folic acid dependent on the pH of the medium (inhibition of the release at an acidic pH -stomach-, controlled release at a neutral pH -intestine-). This capacity makes these developed delivery systems an excellent alternative to direct fortification to successfully modulate the bioaccessibility of folic acid along the gastrointestinal tract. The stability of the supports during an in vitro digestive process was evaluated, and demonstrated that not only small particles can be attacked during the digestion process, but also the functionalization with organic molecules, which act as molecular gates, prevents this attack. Finally, the cell viability studies carried out with four different cell lines revealed that neither the supports nor their degradation products caused any specific toxicity during the in vitro digestive process. The second part evaluates the influence of adding different silica supports to two food matrices: gelatin gels and yoghurts. This technological approach enabled us to know that the capacity of these smart systems to deliver folic acid in a controlled manner during an in vitro digestive process is mantained even after their incorporation in stirred yoghurt. The effect of the matrices on the gel's physical properties depends on the particle size, functionalization and concentration. Finally, this thesis tested that the optimization of folic acid loading, achieved in the first part of the thesis, allowed the fortification of yoghurt with 100% of the recommended daily allowance of folic acid with a very low amount of the system. This fortification affected neither the physico-chemical properties of the yoghurt, nor bacterial viability. In summary, it was concluded that the present thesis globally deals with folic acid encapsulation in silica porous matrices to be used in nutritional and food applications, which include the optimization of loading, release studies at diferent pH, in vitro digestions, stability studies of the employed matrixes, biocompatibility studies, and studies into the influence of their addition to food matrixes. The obtained results positively exhibit that the developed smart folic acid delivery systems open up a new way of fortifying food without endangering the properties of the food to which they are added. / [ES] La presente tesis doctoral que lleva por título "Encapsulación de ácido fólico en soportes porosos de óxido de silicio: una aproximación nutricional y tecnológica" está centrada en el desarrollo de nuevos sistemas inteligentes de liberación controlada de ácido fólico para aplicaciones nutricionales. La primera parte de la tesis muestra la encapsulación de ácido fólico en matrices porosas de óxido de silicio funcionalizadas con poliaminas desde una aproximación nutricional. En ella se ha evaluado la influencia del método de cargado y del tipo de soporte de óxido de silicio utilizado (MCM-41, SBA-15, UVM-7 y Hollow Silica) en la eficacia de encapsulación de ácido fólico. En esta primera parte, también se ha evaluado la influencia de la morfología y el sistema de poros de los diferentes soportes en el perfil de liberación del ácido fólico desde los mismos. Los estudios de liberación de ácido fólico desde los diferentes soportes a diferentes valores de pH han demostrado que los sistemas diseñados son capaces de modular inteligentemente la liberación de ácido fólico en función del pH del medio (inhibición de la liberación a pH ácido -estómago-, liberación controlada a pH neutro -intestino-). Esta capacidad convierte a los sistemas liberación desarrollados en una alternativa excelente a la fortificación directa para modular exitosamente la bioaccesibilidad del ácido fólico a lo largo del tracto gastrointestinal. Por otra parte, se ha evaluado la estabilidad de los soportes durante un proceso de digestión in vitro, demostrando que si bien algunos soportes pueden ser atacados durante la digestión, la funcionalización con moléculas que actúan como puertas moleculares previene este ataque. Por último, los estudios de viabilidad celular llevados a cabo en cuatro tipos de líneas celulares demuestran que ni los soportes, ni los productos de degradación de los mismos durante el proceso de digestión in vitro promueven ningún tipo de toxicidad inespecífica. En la segunda parte se ha evaluado la influencia de la adición de diferentes soportes de óxido de silicio a dos matrices alimentarias, geles de gelatina y yogures. Esta aproximación tecnológica ha permitido conocer que la capacidad de estos sistemas inteligentes para liberar controladamente el ácido fólico a lo largo de un proceso de digestión in vitro se mantiene incluso tras su incorporación en yogures batidos. Por otra parte, se ha comprobado que el efecto de las matrices sobre las propiedades físicas de los geles, es dependiente tanto del tamaño de las partículas, como de su funcionalización y concentración. Por último, se ha comprobado que debido a la optimización del cargado de ácido fólico alcanzada en la primera parte de la tesis, se puede lograr una fortificación de un yogur con el 100% de la cantidad diaria recomendada de ácido fólico con una cantidad tan pequeña de sistema que ni las propiedades físico-químicas de un yogur, ni la viabilidad bacteriana se ven comprometidas. En resumen, se puede concluir que la presente tesis ha abordado de una manera global la encapsulación de ácido fólico en matrices porosas de óxido de silicio para ser utilizados en aplicaciones nutricionales y alimentarias incluyendo estudios de optimización de cargado, estudios de liberación en función del pH, digestiones in vitro, estudios de estabilidad de las matrices utilizadas, estudios de biocompatibilidad, así como estudios de la influencia de la adición de estos sistemas inteligentes en matrices alimentarias. Los resultados obtenidos han puesto de manifiesto que los sistemas inteligentes de liberación de ácido fólico desarrollados abren la puerta a una nueva manera de fortificar los alimentos sin comprometer sus características. / [CA] La present tesi doctoral, que porta per títol "Encapsulació d'àcid fòlic en suports porosos d'òxid de silici: una aproximació nutricional i tecnològica" està centrada en el desenvolupament de nous sistemes intel·ligents de lliberació controlada d'àcid fòlic per a aplicacions nutricionals. La primera part de la tesi mostra l'encapsulació d'àcid fòlic en matrius poroses d'òxid de silici funcionalitzades amb poliamines des d'una aproximació nutricional. En esta part, s'ha avaluat la influència del mètode de carrega i del tipus de suport d'òxid de silici que s'ha emprat (MCM-41, SBA-15, UVM-7 i Hollow Silica) en l'eficàcia de l'encapsulació d'àcid fòlic. En esta primera part, també s'ha avaluat la influència de la morfologia i el sistema de porus dels diferents suports en el perfil d'alliberament de l'àcid fòlic des dels mateixos. Els estudis d'alliberament d'àcid fòlic des dels diferents suports a diferents valors de pH han demostrat que els sistemes dissenyats són capaços de modular intel¿ligentment l'alliberament d'àcid fòlic en funció del pH del medi (inhibició de l'alliberament a pH àcid -estómac-, alliberament controlat a pH neutre -intestí-). Esta capacitat fa dels sistemes desenvolupats una excel·lent alternativa a la fortificació directa per a modular amb èxit la bioaccessibilitat de l'àcid fòlic a través del tracte gastrointestinal. D'altra banda, s'ha avaluat l'estabilitat dels suports en un procés de digestió in vitro, demostrant que mentre que les partícules menudes poden ser atacades durant la digestió, la funcionalització amb molècules orgàniques que actuen com a portes moleculars prevé aquest atac. Per últim, els estudis de viabilitat cel·llular duts a terme en quatre tipus de línies cel·lulars demostren que ni els soports, ni els productes de degradació dels mateixos durant el procés de digestió in vitro promouen cap tipus de toxicitat inespecífica. En la segona part, s'ha avaluat la influència de l'addició de diferents sopors d'òxid de silici a dos matrius alimentàries, gels de gelatina i iogurts. Esta aproximació tecnològica ha permés conéixer que la capacitat d'aquests sistemes intel·ligents per alliberar controladament àcid fòlic durant un procés de digestió in vitro es manté fins i tot després de ser incorporats en iogurts batuts. D'altra banda, s'ha comprovat que l'efecte de les matrius sobre les propietats físiques dels gels, és dependent tant de la grandària de les partícules, com de la seua funcionalització i concentració. Per últim, s'ha comprovat que a causa de l'optimització del carregat d'acid fòlic alcançada en la primera part de la tesi, es pot aconseguir una fortificació d'un iogurt amb el 100% de la quantitat diària recomanada d'àcid fòlic amb una quantitat tan baixa del sistema que ni les propietats físico-químiques d'un iogurt, ni la viabilitat bacteriana se'n veuen compromeses. En resum, es pot concluir que en la present tesi s'ha abordat d'una manera global l'encapsulació d'àcid fòlic en matrius poroses d'òxid de silici per a ser utilitzades en aplicacions nutricionals i alimentàries, que inclouen estudis d'optimització de carregat, estudis d'alliberament en funció del pH, digestions in vitro, estudis d'estabilitat de les matrius utilitzades, estudis de biocompatibilitat, així com estudis de la influència de l'addició d'aquests sistemes en matrius alimentàries. Els resultats obtesos han posat de manifest de forma positiva que els sistemes intel·ligents d'àcid fòlic que s'han desenvolupat obrin una porta a una nova manera de fortificar els aliments sense comprometre les seues caracterísitiques. / Pérez Esteve, E. (2015). ENCAPSULATION OF FOLIC ACID IN MESOPOROUS SILICA SUPPORTS: A NUTRITIONAL AND TECHNOLOGICAL APPROACH [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/58613 / TESIS / Premios Extraordinarios de tesis doctorales / Compendio

Folic acid

Bioaccessibility

Mesoporous silica particles

Nutrition

Digestion

Stability

Controlled release

QUIMICA INORGANICA

TECNOLOGIA DE ALIMENTOS