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New techniques for the fabrication of biosensors based on nad (P) + dependent dehydrogenasesPaulov, Valeri 28 January 2005 (has links)
DE LA TESIS EN CASTELLANOAntecedentesUn avance importante en el campo de química analítica se hizo por Clark y Lyons en los años setenta. Ellos propusieron acoplar la especificidad de la enzima glucosa oxidasa con la transducción electroquímica de la señal en "biosensores". En general, los biosensores son artefactos integrados autocontenidos, capazes de proporcionar información analítica, cuantitativa utilizando un elemento biológico de reconocimiento (receptor bioquímico) que se retiene en contacto espacial directo con un elemento de transducción. Posteriormente, los primeros biosensores de glucosa, basados en la detección amperométrica de peróxido de hidrógeno generado por glucosa oxidasa en la presencia de oxígeno fueron introducidos en el mercado por la empresa estadounidense Yellow Spring Instrument Co. (Ohio, EE. UU.) en 1975. La respuesta de biosensores electroquímicos basados en el uso de oxígeno como cosustrato para oxidasas se ve desviada por la presencia de interferencias que pueden contribuir a la corriente. Por lo tanto la superficie de electrodo debe estar protegida por una membrana no permeable por sustancias que pueden interferir con la señal. Para evitar corrientes que perjudican la selectividad de los biosensores, el potencial aplicado puede ser aminorado usando electrocatalizadores difusionales ("mediadores") en lugar de oxígeno, con un potencial redox controlable. Pero la respuesta de estos sensores también depende de la concentración de oxígeno porque este compite con los mediadores, para la reoxidación de las oxidasas. Un inconveniente adicional del uso de mediadores diffusionales artificiales en biosensores es la baja estabilidad de los mismos debida al escape de mediadores desde la superficie del electrodo cuando esto se usa en linea. Se puede aliviar este problema creando enlaces covalentes entre los mediadores y la superficie del electrodo o usando polímeros redox que se adsorben fućrtemente en la superficie del electrodo. Una de las posibles maneras para disminuir la influencia del oxígeno a la corriente de la respuesta de biosensores es el uso de las deshidrogenasas dependientes de la pareja redox NAD+/NADH. El potencial estándar redox de esta pareja es -0.56 V vs. SCE pero para conseguir la oxidación de NADH en la superficie de electrodos de carbono un sobrepotencial de +0.5 V vs. SCE debe aplicarse. Bajo estas condiciones los electrodos tienen tiempo de vida corto debido a la adsorción de los productos de oxidación en su superficie ya que la oxidación de NADH no es reversible químicamente. Por otro lado estos electrodos sufren por la oxidación no especifica de interferencias a estos potenciales de operación. Los electrodos modificados químicamente por mediadores pueden oxidar NADH a potenciales más bajos. Sin embargo, muchos de los mediadores mencionados en la bibliografía no son estables o/y no forman NAD+ enzimaticamente activo. Un problema adicional de los sistemas analíticos basados en deshidrogenasas dependientes de NAD+ es la necesidad de añadir este cofactór, que tiene alto coste y es inestable, en las muestras. Se puede inmovilizar NAD+ en la superficie de electrodos para producir biosensores capaces de funcionar en muestras que no contienen NAD+, biosensores reagentless (sin necesidad de adición de reactivos). Los métodos descritos en la bibliografía para la fabricación de biosensores reagentless se basan en cinco estrategias: (1) la inmovilización en hidrogeles formados in situ; (2) la inmovilización por una membrana; (3) la inmovilización en películas preparadas por electropolimerización; (4) la inmovilización en una pasta de carbono; (5) la inmovilización en monocapas auto ensambladas. Sólo los electrodos preparados con la estrategia (4) son biosensores reagentless con estabilidad operacional relativamente alta. Las demás estrategias no resultan en biosensores con suficiente estabilidad operacional por culpa de la perdida del mediador, de NAD+ o de la deshidrogenasa. Sin embargo la estrategia basada en electrodos de pasta de carbono no permite su aplicación a la producción de microsensores (electrodos con diámetro de menos de 10 m) para su uso in vivo. MetodologíaEl objetivo principal de esta tesis es el desarrollo de nuevas estrategias para la fabricación de biosensores reagentless basados en deshidrogenasas dependientes de NAD+ con características mejoradas respecto a la densidad de la corriente, de la estabilidad operacional y de almacenamiento. Para cumplir el objetivo se han sintetizado dos nuevos mediadores para la oxidación de NADH: un polímero insoluble en agua [Os(1,10-fenantrolina-5,6-diona)2(PVP)4Cl]Cl, (Os-fendiona-PVP) y un complejo amfifílico [Os(1,10-fenantrolina-5,6-diona)24,4'-(n-C18H37NHCO)2bpi)](PF6)2 (Os-fendiona-surfactante). El polímero Os-fendiona-PVP fue producido vía la derivatización de poli(vinilpiridina) (peso molecular 50000) con [Os(1,10-fenantrolina-5,6-diona)2Cl2]. El estudio electroquímico de este polímero redox adsorbido en electrodos de grafito se realizó por voltametría cíclica a distintas velocidades de barrido para evaluar el número de protones y electrones que participan en la reacción redox, la influencia del pH a su potencial estándar formal, y la constante de la transferencia heterogénea del electrónes kS. Bajo bien definidas condiciones hidrodinámicas se realizaron estudios para encontrar la constante de la interacción con NADH k[NADH]=0. Os-fendiona-surfactante fue producido por la complejacion de [Os(1,10-fenantrolina-5,6-diona)2]Cl2 con el ligando hidrófobo octadodecilamida del acido 2,2'-Bipiridina-4,4'-dicarboxilico. Las monocapas de Langmuir-Blorgett de Os-fendiona-surfactante y las de su análogo [Os(bpi)24,4'-(n-C18H37NHCO)2bpi)](PF6)2 fueron estudiados en un equipo de Langmuir-Blodgett. Os-fendiona-surfactante fue aplicado a la construcción de biosensores reagentless del glutamato vía la inmovilización de glucosa deshidrogenasa y de NAD+ entre las bicapas en la fase lamelar formada por Os-fendiona-surfactante y el lípido 1,2-dioleoilo-sn-glicero-3-fosfatidilcolina. Dos métodos adicionales para la fabricación de los biosensores reagentless de glutamato y glucosa basados en deshidrogenasas fueron desarrollados. Los electrodos del grafito fueron modificados con Os-fendiona-PVP y utilizados para (a) la inmovilización de deshidrogenasa y de NAD+ en un hidrogel formado por entercruzamiento de poli(vinilpiridina) modificado por grupos amino con el éter diglicidil de poli(etilenglicol); (b) la inmovilización por adsorción de la deshidrogenasa y del ácido algínico modificado por NAD+. Se ha hecho un estudio de los biosensores reagentless para calcular sus constantes de Michaelis, el efecto del pH y de la temperatura en su respuesta y su estabilidad operacional. Además se ha comparado la estabilidad operacional a temperaturas elevadas de biosensores de la configuración (a) usando glutamato, glucosa y glucosa-6-fosfato deshidrogenasas termófilas y mesófilas. Por otro lado se han estudiado métodos nuevos para mejorar le estabilidad durante el almacenamiento de sensores de glutamato. Con este fin, se han preparado electrodos utilizando glutamato deshidrogenasa mesófila y termófila con varios estabilizadores. Conclusiones1. El polímero [Os(1,10-fenantrolina-5,6-diona)2(PVP)4Cl]Cl, (Os-fendiona-PVP) para la oxidación de NADH se puede sintetizar por la complejación de [Os(1,10-fenantrolina-5,6-diona)2Cl2] con poli(vinilpiridina). La adsorción física de este polímero sobre los electrodos de grafito desde su solución en etilenglicol resulta en la formación de una monocapa de este polimero redox en la superficie del electrodo. 2. El proceso redox de este mediador es casi-reversible e implica 4 electrones y 4 protones dentro del rango del pH de 3-6.5. El mediador pierde su estabilidad química en valores de pH más altos que 6.5. Tres ramas lineales en el diagrama de E0' frente a pH con diversas pendientes se observan. 3. La constante heterogénea de la velocidad de transferencia de electrones (kS) de Os-fendiona-PVP es del mismo orden de magnitud que la de otros mediadores capaces de oxidar NADH mencionados en la bibliografía (kS= 18±2 s-1) . 4. Os-fendiona-PVP es un electrocatalizador eficiente para la oxidación del NADH. La modificación de los electrodos del grafito con Os-fendiona-PVP conduce a la disminución del sobrepotential para la oxidación electroquímica del NADH desde +0.33 V vs. Ag/AgCl/KClsat para los electrodos no modificados hasta +0.11 V vs. Ag/AgCl/KClsat. La constante cinética para la interacción del polímero redox con el NADH (k1,[NADH]=0 = (1.9±0.2)x103 s-1 M-1) coincide prácticamente con la de Os-fendiona que sugiere que el número de los ligandos de fendiona en los complejos del osmio es proporcional a la corriente de la respuesta al NADH pero no afecta a las constantes cinéticas electroquímicas. / The objective of this work was the development of new configurations of reagentless biosensors based on NAD+ dependent dehydrogenases. These configurations are based on the immobilisation of enzyme, cofactor and the electrochemical catalyst used for its regeneration. In addition to being reagentless these configurations yielded biosensors with improved current density and operational stability compared to the state of the art. To achieve the objective two new NADH oxidising mediators were synthesised: a water insoluble polymer [Os(1,10-phenanthroline-5,6-dione)2(PVP)4Cl]Cl (Os-phendione-PVP) and an amphiphilic complex [Os(1,10-phenanthroline-5,6-dione)24,4'-(n-C18H37NHCO)2bpy)](PF6)2 (Os-phendione-surfactant). The electrochemical study of Os-phendione-PVP has revealed a rate constant for the heterogeneous electron transfer of the phendione redox couple ks = 252 s-1, and a second order rate constant for NADH oxidation k[NADH]=0=(1.10.1)x103 M-1 s-1. These constants are higher or of the same order of magnitude as those of previously described NADH oxidising mediators. The tensoactive mediators Os-phendione-surfactant and its analogue [Os(bpy)24,4'-(n-C18H37NHCO)2bpy)](PF6)2 (Os-bpy-surfactant) form very stable monolayers at the air-water interface collapsing at the surface pressure 60-65 mN m-1. The Os-phendione-surfactant was used for the construction of reagentless glutamate biosensors via the immobilisation of dehydrogenase and NAD+ between bilayers in lamellar phase formed by Os-phendione-surfactant and the lipid 1,2-dioleoyl-sn-glycero-3-phosphatidylcholine. The resulting glutamate biosensors demonstrated maximum current density of 3.5 A cm-2 (RSD=25%), apparent Michaelis constant of 47 mM, and operational half life of 0.5 h. In addition graphite electrodes were modified by Os-phendione-PVP and utilised for (a) immobilisation of dehydrogenase and NAD+ in a hydrogel formed by crosslinking of poly(vinylpyridine) carrying amino groups with polyethylene glycol diglycidyl ether and (b) immobilisation of dehydrogenase and an NAD+-alginic acid derivative by adsorption. The configuration (a) yielded glutamate sensors with maximum current density of 8.7 A cm-2 (RSD=5%), apparent Michaelis constant of 9.1 mM, operational half life of 12 h and glucose sensors with maximum current density of 37 A cm-2 (RSD=14%), apparent Michaelis constant of 4.2 mM, the operational half life of 1 h. The glutamate sensors based on the configuration (b) showed maximum current density of 15.8 A/cm2 (RSD=21%), apparent Michaelis constant of 17.6 mM and operational half life of 1.5 h. Glucose, glucose-6-phosphate, and glutamate biosensors were prepared and characterised. The employment of the thermophilic enzymes helps to dramatically increase the operational stability of biosensors at elevated temperatures higher than 60oC. The shelf life of glutamate electrodes built with the use of thermophilic dehydrogenase was eleven times longer than this of electrodes modified with the mesophilic enzyme. The addition of the copolymer of vinyl-pyrrolidone and dimethylamino ethyl methacrylate termed as Gafquat HS100 to the enzyme also significantly improved shelf life
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Enhancement of the Response Range and Longevity of Microparticle-based Glucose SensorsSingh, Saurabh 2010 May 1900 (has links)
Luminescent microspheres encapsulating glucose oxidase and an oxygensensitive
lumophore have recently been reported as potential implantable sensors for in
vivo glucose monitoring. However, there are two main issues that must be addressed for
enzymatic systems such as these to realize the goal of minimally-invasive glucose
monitoring. The first issue is related to the short response range of such sensors, less
than 200 mg/dL, which must be extended to cover the full physiological range (0-600
mg/dL) of glucose possible for diabetics. The second issue is concerning the short
operating lifetime of these systems due to enzyme degradation (less than 7 days).
Two approaches were considered for increasing the range of the sensor response;
nanofilm coatings and particle porosity. In the first approach, microparticle sensors were
coated with layer-by-layer deposited thin nanofilms to increase the response range. It
was observed that, a precise control on the response range of such sensors can be
achieved by manipulating different characteristics (e.g., thickness, deposition condition,
and the outermost capping layer) of the nanofilms. However, even with 15 bilayers of poly(allylamine hydrochloride)/poly(styrene sulfonate) (PAH/PSS) nanofilm, limited
range was achieved (less than 200 mg/dL). By performing extrapolation on the data
obtained for the experimentally-determined response range versus the number of
PAH/PSS bilayers, it was predicted that a nanofilm coating comprising of more than 60
PAH/PSS bilayers will be needed to achieve a linear response up to 600 mg/dL.
Using modeling, it was realized that a more effective method for achieving a
linear response up to 600 mg/dL is to employ microparticles with higher porosity.
Sensors were prepared from highly porous silica microparticles (diameter = 7 mu m,
porosity = 0.6) and their experimental response was determined. Not surprisingly, the
experimentally determined response range of such sensors was found to be higher than
600 mg/dL.
To improve the longevity of these sensors, two approaches were employed;
incorporation of catalase and increasing the loading of glucose oxidase. Catalase was
incorporated into microparticles, which protects the enzyme from peroxide-mediated
deactivation, and thus improves the stability of such sensors. Sensors incorporating
catalase were found to ~5 times more stable than the GOx-only sensors. It was
theoretically predicted, that by maximizing the loading of glucose oxidase within the
microparticles, the longevity of such sensors can be substantially improved. Based on
this understanding, sensors were fabricated using highly porous microparticles; response
range did not vary even after one month of continuous operation under normal
physiological conditions. Modeling predicts that 1 mM of glucose oxidase and 1 mM of
catalase would extend the operating lifetime to more than 90 days.
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Design and Fabrication of a Membrane Integrated Microfluidic Cell Culture Device Suitable for High-Resolution ImagingEpshteyn, Alla 31 December 2010 (has links)
Malaria remains a serious concern for people living and traveling to warm climates in Africa, Asia, and some parts of America. Understanding the mechanism of the malaria parasite in the liver phase could lead to important discoveries for preventative and treatment therapeutics before the disease develops into the blood stage. While in vitro liver cell culture models have been explored, a device that mimics the liver cell architecture with the capability of high-resolution imaging has never been created. In this research, a cell culture microfluidic device was designed and fabricated with a membrane integrated design to mimic the architecture of a liver, cell chamber dimensions affable for high-resolution imaging, and fluidic port design for optical access to both sides of the membrane for the study of malaria parasite invasion.
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A Study of Porous Transitions of Layer-By-Layer Thin Films and Patterning MultilayersCho, Chungyeon 16 December 2013 (has links)
This thesis research focuses on fundamental understanding regarding the morphological transitions of weak polyelectrolyte multilayers (PEMs) formed by the layer-by-layer (LbL) electrostatic assembly of oppositely charged polymers.
he first part of this thesis focuses on patterning polyelectrolyte multilayers that are able to undergo transitions from continuous films to porous materials by using hydrogel stamps. The stamping process is able to locally etch and pattern the porous transition in the LbL films by using reactive wet stamping (r-WETS). It was found that r-WETS of PEMs can also enable the modification of chemical functionality.
The second part is an investigation about morphological changes of weak polyelectrolyte multilayers assembled with PAH and PAA using r-WETS in which hydrogel stamp material was soaked into various salt solutions and then applied to the LbL films. Also, in this study we presented a novel strategy to create a continuous gradient structure in thickness or porosity along the lateral direction of the thin films using concentration gradient salt stamping.
The third part is an investigation regarding the mechanism of the transition from a continuous morphology to a porous morphology within weak polyelectrolyte multilayers. These morphological changes were able to be created by both acidic and basic post-assembly treatments, showing various morphological transitions from the introduction of porosity to the collapse of these porous structures and the eventual dissolution of the films.
A similar observation of morphological transitions in weak polyelectrolyte multilayers was obtained by applying an electric field to the films in the fourth part of this thesis. Exposure to an electric field resulted in the creation of a porous structure, which can be ascribed to local changes in pH and subsequent structural rearrangements of the weak polyelectrolyte constituents.
The final part of this thesis is to make PEMs into nanostructured matrices for inorganic synthesis. Multilayers possessing ion-exchangeable carboxylic acid groups were used for binding metal catalysts such as platinum (Pt) nanoparticles (NPs) within the film. Therefore, polyelectrolyte multilayers were able to stabilize catalytic Pt NPs in order to increase the useful time of catalyst materials suitable for use in proton exchange membrane fuel cells.
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Layer-by-Layer Assemblies for Membrane-Based Enzymatic CatalysisTomaino, Andrew R 01 January 2014 (has links)
While considerable progress has been made towards understanding the effect that membrane-based layer-by-layer (LbL) immobilizations have on the activity and stability of enzymatic catalysis, detailed work is required in order to fundamentally quantify and optimize the functionalization and operating conditions that define these properties. This work aims to probe deeper into the nature of transport mechanisms by use of pressure-induced, flow-driven enzymatic catalysis of LbL-functionalized hydrophilized poly(vinyldiene) (PVDF)-poly(acrylic acid) (PAA)-poly(allylamine hydrochloride) (PAH)-glucose oxidase (GOx) membranes. These membranes were coupled in a sealed series following cellulose acetate (CA) membranes for the elimination of product accumulation within the feed-side solution during operation. At pH = 6 and T = 21oC, the enzymatic catalysis of LbL-immobilized GOx from Aspergillus niger performed remarkably well in comparison to the homogeneous-phase catalysis within an analogous aqueous solution. On average, the enzymatic turnover was 0.0123 and 0.0076 mmol/(mg-GOx)(min) for the homogeneous-phase catalysis and the LbL-immobilized catalysis, respectively. Multiple consecutive permeations resulted in replicable observed kinetic results with R2 > 0.95. Permeations taking place over the course of a three week trial period resulted in a retention of >90% normalized activity when membranes were removed when not in use and stored at -20oC, whereas the homogenous-phase kinetics dropped below 90% normalized activity in under one day.
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Inkjet-assisted printing of encapsulated polymer/biopolymer arraysSuntivich, Rattanon 27 August 2014 (has links)
The goal of the proposed study is to understand the morphology, physical, and responsive properties of synthetic polymer and biopolymer layer-by-layer (LbL) arrays using the inkjet printing and stamping technique, in order to develop patterned encapsulated thin films for controlled release and biosensor applications. In this study, we propose facile fabrication processes of hydrogen-bonded and electrostatic LbL microscopic dot arrays with encapsulated target organic and cell compounds. We study encapsulation with the controllable release and diffusion properties ofpoly(vinylpyrrolidone) (PVPON), poly(methacrylic acid) (PMAA), silk-polylysine, silk-polyglutamic acid, pure silk films, and E-coli cells from the multi-printing process. Specifically, we investigate the effect of thickness, the number of bilayers, and the hydrophobicity of substrates on the properties of inkjet/stamping multilayer films such as structural stability, responsiveness, encapsulation efficiency, and biosensing properties.
We suggest that a more thorough understanding of the LbL assembly using inkjet printing and stamping techniques can lead to the development of encapsulation technology with no limitations on either the concentration of loading, or the chemical and physical properties of the encapsulated materials. In addition, this study offers new encapsulation concepts with simple, cost effective, highly scalable, living cell-friendly, and controllable patterning properties.
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Layer-by-layer Electrode Modification for Electrochemical Capacitors - Alternative Cations and Process OptimizationXiao, Weixiao 07 July 2014 (has links)
Layer-by-Layer (LbL) deposition of electrochemically active materials on porous carbon electrodes is a proven method to leverage both electrochemical double-layer capacitance and pseudocapacitance for charge storage on the same electrode. LbL coatings are held together by electrostatic attraction between adjacent layers of oppositely charged molecules. Previous studies have used Keggin polyoxometalates to great effect as the anionic layer in LbL electrode modification, but little effort has been devoted to cationic material selection and LbL process optimization. This work investigated alternatives to the conventional, electrochemically inert polydiallyldimethylammonium (PDDA) cation. The use of fuchsin molecular cations in LbL deposition improved the specific energy and specific power of modified electrodes. Fuchsin cation also rendered the environmentally harmful oxidative surface activation step unnecessary for LbL deposition. Process parameters were optimized for MWCNT/Fuchsin/POM samples, and post-LbL electrochemical polymerization was found to further improve the performance of these electrodes.
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Transport-Controlling Nanoscale Multilayers for Biomedical DevicesPark, Jae Bum 2012 August 1900 (has links)
Recent advances in multilayer self-assembly have enabled the precise construction of nanocomposite ultrathin films on a variety of substrates, from large-area planar surfaces to nanoparticles. As a result, a wide range of physico-chemical properties may be represented by selecting from an array of surface preparations, molecules, assembly conditions, and post-assembly treatments. Such multilayer nanofilm assemblies are particularly attractive for use as specialized membranes for selective transport, which have many applications for separations, sensors, and drug delivery systems.
In this work, nanocomposite ultrathin films built with layer-by-layer (LbL) self-assembly methods have been applied to surface modification to control interfacial behavior, including diffusion, anti-fouling, and biomimetic membranes. Transport and interfacial properties of nanocomposite membranes constructed using LbL self-assembly with synthetic and/or bio-polymers were characterized, and permeability values of clinically relevant small molecules through the nanofilms were determined. Correlations between permeability and film properties were also examined.
Nanofilm coatings around 100nm thickness decreased diffusion coefficients of glucose up to five orders of magnitude, and were found to greatly affect enzymatic glucose sensor responses. Surface modification on top of the nanofilms with poly(ethylene glycol) provided anti-fouling effects. However, weak-weak polyelectrolyte multilayers (PEMs) should not be used to control transport due to their susceptibility under normal physiological conditions. Natural/biological polymers also provided multilayer film structures at the specific conditions, but their transport-limiting properties were not significant compared to synthetic PEMs. Even when covalently crosslinked, biological PEMs did not reduce the permeability of a small molecule. Finally, the predicting model of projecting analyte permeation through multi-phase nanocomposite films comprised with known diffusion coefficients was theoretically and experimentally evaluated. The modeling was matched reasonably well to experimental data.
The outcomes will be the key knowledge or engineering principles to support future efforts in research and development. It is anticipated that the system developed for determining transport properties will provide a general platform for assessing new candidate materials. The theory developed will be useful in estimating transport properties of novel nanocomposite materials that may be interesting in a broad array of chemical and biological systems, from analytical separations to implantable biomedical applications, and will provide useful design rules for materials and fabrication process selection.
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Processing and Gas Barrier Behavior of Multilayer Thin Nanocomposite FilmsYang, You-Hao 2012 August 1900 (has links)
Thin films with the ability to impart oxygen and other types of gas barrier are crucial to commercial packaging applications. Commodity polymers, such as polyethylene (PE), polycarbonate (PC) and polyethylene terephthalate (PET), have insufficient barrier for goods requiring long shelf life. Current gas barrier technologies like plasma-enhanced vapor deposition (PECVD) often create high barrier metal oxide films, which are prone to cracking when flexed. Bulk composites composed of polymer and impermeable nanoparticles show improved barrier, but particle aggregation limits their practical utility for applications requiring high barrier and transparency. Layer-by-layer (LbL) assemblies allow polymers and nanoparticles to be mixed with high particle loadings, creating super gas barrier thin films on substrates normally exhibiting high gas permeability.
Branched polyethylenimine (PEI) and poly (acrylic acid) (PAA) were deposited using LbL to create gas barrier films with varying pH combinations. Film thickness and mass fraction of each component was controlled by their combined charge. With lower charge density (PEI at pH 10 and PAA at pH 4), PEI/PAA assemblies exhibit the best oxygen barrier relative to other pH combinations. An 8 BL PEI/PAA film, with a thickness of 451 nm, has an oxygen permeability lower than 4.8 x 10^-21 cm^3 * cm/cm^2 * s * Pa, which is comparable to a 100 nm SiOx nanocoating. Crosslinking these films with glutaraldehyde (GA), 1-[3-(dimethylamino)propyl]-3-ethylcarbodiimide methiodide (EDC) or heating forms covalent bonds between PEI and/or PAA. Oxygen transmission rates (OTR) of 8 BL films crosslinked with 0.1M GA or 0.01M EDC show the best oxygen barrier at 100% RH.
Graphene oxide (GO) sheets and PEI were deposited via LbL with varying GO concentration. The resulting thin films have an average bilayer thickness from 4.3 to 5.0 nm and a GO mass fraction from 88 to 91wt%. Transmission electron microscopy and atomic force microscopy images reveal a highly-oriented nanobrick wall structure. A 10 BL PEI/GO film that is 91 nm thick, made with a 0.2 wt% GO suspension, exhibits an oxygen permeability of 2.5 x 10^-20 cm^3 * cm/cm^2 * s * Pa.
Finally, the influence of deposition time on thin film assembly was examined by depositing montmorillonite (MMT) or laponite (LAP) clays paired with PEI. Film growth and microstructure suggests that smaller aspect ratio LAP clay is more dip-time dependent than MMT and larger aspect ratio MMT has better oxygen barrier. A 30 BL PEI/MMT film made with 10 second dips in PEI has the same undetectable OTR as a film with 5 minute dips (with dips in MMT held at 5 minutes in both cases), indicating LbL gas barrier can be made more quickly than initially thought. These high barrier recipes, with simple and efficient processing conditions, are good candidates for a variety of packaging applications.
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Techniques for the detection and development of part I. detection of ozone for water treatment part II. utilizing layer-by-layer thin films with long period grating fibers /Puckett, Sean D. January 2006 (has links)
Thesis (Ph. D.)--Miami University, Dept. of Chemistry and Biochemistry, 2006. / Title from first page of PDF document. Includes bibliographical references.
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