Global ETD Search

21	An intracellular glucose biosensor based on nanoflake ZnO Fulati, Alimujiang, Usman Ali, Syed M., Asif, Muhammad H., Hassan Alvi, Naveed Ul, Willander, Magnus, Brännmark, Cecilia, Strålfors, Peter, Börjesson, Sara I., Elinder, Fredrik, Danielsson, Bengt January 2010 (has links) In this study, an improved potentiometric intracellular glucose biosensor was fabricated with immobilization of glucose oxidase on a ZnO nanoporous material. The ZnO nanoporous material with a wall thickness around 200 nm was grown on the tip of a borosilicate glass capillary and used as a selective intracellular glucose sensor for the measurement of glucose concentrations in human adipocytes and frog oocytes. The results showed a fast response within 4 s and a linear glucosedependent electrochemical response over a wide range of glucose concentration (500 nM-10 mM). The measurements of intracellular glucose concentrations with our biosensor were consistent with the values of intracellular glucose concentrations reported in the literature. The sensor also demonstrated its capability by detecting an increase in the intracellular glucose concentration induced by insulin. We found that the ZnO nanoporous material provides sensitivity as high as 1.8 times higher than that obtained using ZnO nanorods under the same conditions. Moreover, the fabrication method in our experiment is simple and the excellent performance of the developed nanosensor in sensitivity, stability, selectivity, reproducibility and anti-interference was achieved. All these advantageous features of this intracellular glucose biosensor based on functionalised ZnO nanoporous material compared to ZnO nanorods demonstrate a promising way of enhancing glucose biosensor performance to measure reliable intracellular glucose concentrations within single living cells. / <p>Original Publication:Alimujiang Fulati, Syed M. Usman Ali, Muhammad H. Asif, Naveed Ul Hassan Alvi, Magnus Willander, Cecilia Brännmark, Peter Strålfors, Sara I. Börjesson and Fredrik Elinder, An intracellular glucose biosensor based on nanoflake ZnO, 2010, Sensors and actuators. B, Chemical, (150), 2, 673-680.http://dx.doi.org/10.1016/j.snb.2010.08.021Copyright: Elsevier Science B.V., Amsterdam.http://www.elsevier.com/</p> Glucose oxidase (GOD) Intracellular Potentiometric biosensor Nanoflake ZnO Nafion membrane NATURAL SCIENCES NATURVETENSKAP
22	Vapor-Liquid-Solid(VLS) Grown Silica (SiOx) Nanowires as the Interface for Biorecognition Molecules in Biosensors Murphy-Pérez, Eduardo 01 January 2013 (has links) SiOx nanowires grown through the VLS mechanism were electrophoretically deposited on top of Au electrodes. GOx was immobilized using APTES and the EDC-NHS chemistry. Cyclic Voltammetry was used as the method to characterize the electrodes through their processing steps, and CV was also used to detect glucose in a PBS based solution. Ferro-Ferri Cyanide couple was used as the mediator. Biosensor Glucose Glucose Oxidase Nanowires Silica-W SiOx Electrical and Computer Engineering Engineering
23	Electrochemical studies of monosubstituted squarate ligands and its transition metal and lanthanide complexes. Mohamed, Nuralli. January 2008 (has links) <p>The study introduces and puts forward Sector Policing as a model to expand community Policing and to broaden the scope of crime prevention. It also demonstrates how Sector Policing can be utilised to decentralise policing and deepen community participation.</p> Monosubstituted ligand electrochemistry DMF DMSO DCM glucose oxidase/glucose mediator.
24	FUNCTIONALIZED POLYMERIC MEMBRANES FOR BIOSEPARATION AND BIOCATALYSIS Datta, Saurav 01 January 2007 (has links) Functionalized polymeric membrane based techniques are becoming increasingly popular in biotechnology, food and pharmaceutical industries due to their versatility and hydrodynamic benefits over traditional materials and methods. This research work has been directed towards the development of functionalized polymeric membranes, extensive experimental and theoretical analyses of some of the fundamental aspects of accessibility, membrane fouling and enzyme catalysis, and applications in affinity based bioseparation and biocatalysis. In this research work, the impact of different types of functionalization techniques, such as functionalization of different membrane materials, covalent and electrostatic immobilization, on interaction of various biomolecules and active sites in membrane has been studied in detail. Avidin was used as model biomolecule, and covalently immobilized within acyl anhydride derivatized nylon based membrane. Quantification of the accessibility of covalently immobilized avidin sites was carried out by model biotinylated probe molecules, such as biotin 4-amidobenzoic acid and biotinylated-BSA. This study has been further extended to separate and purify a target protein, HIV-Tat, from a complex mixture of proteins (97-99 % unwanted protein) using avidin-biotin affinity interaction. It has been demonstrated that covalent immobilization of avidin in membranes reduces the accessibility of active sites for probe molecules. Accessibility decreases further for the biotinylated target protein present in the mixture of other unwanted proteins. Affinity based membrane separation of proteins is also associated with decrease in permeate flux due to fouling in membrane structure. Fouling in the membrane has been discussed by analyzing the characteristics of adsorbed protein layer in membrane. In order to improve the accessibility and fouling behavior of affinity separation of Tat protein, a pre-filtration step has been introduced prior to affinity separation. Significant enhancement in accessibility and reduction in fouling has been observed for pre-filtered cases as it removes unwanted proteins prior to affinity interaction. Contribution of the pre-filtration step in reduction of fouling has been elucidated by simple model equations. Improvement in accessibility and fouling behavior reflects in higher separation efficiency (protein recovery) and lower processing time for the pre-filtered cases. Quality of membrane purified Tat protein was examined by different analytical techniques, such as SDS-PAGE, Western Blot and biotin analysis, and then compared with that purified by traditional packed-bead column chromatography. It has been demonstrated that membrane based technique was able to isolate superior quality of pure monomeric Tat protein compare to column chromatographic technique. The other study carried out as a part of this dissertation, has involved development of high capacity, highly active, stable and reusable functionalized membrane domains for electrostatic immobilization of enzymes. Glucose oxidase (GOX) was used as a model enzyme to study the oxidation of glucose to gluconic acid and hydrogen peroxide under convective flow condition. Two different approaches of functionalization of membranes have been presented. In the first approach, alternative electrostatic attachment of cationic and anionic polyelectrolytes was carried out using Layer-By-Layer (LBL) assembly technique within a functionalized nylon based membrane. In the second one, a hydrophobic PVDF membrane was functionalized by in-situ polymerization of acrylic acid. Kinetics of glucose oxidation, effect of pH and flow rate on the activity of GOX was discussed. A comparative study was presented between the activity of free GOX, electrostatically immobilized GOX and covalently immobilized GOX, along with the advantage of convective mode of operation over soaking mode. A novel study has also been conducted on detachment and reattachment of GOX in the same membrane matrix. Further study has been directed towards implementation of the above mentioned immobilized enzymatic system for oxidative dechlorination of chloro-organics. A first time attempt was made to use a 2-stack functionalized membranes system for simultaneous enzymatic production of hydrogen peroxide in first membrane, and oxidative dechlorination of 2, 4, 6-trichlorophenol (TCP) in the Fe+2 immobilized (by ion exchange) second membrane by Fenton reaction. The technique was efficient in destruction of TCP as evident from the overall dechlorination of 70-80 %. This technique provides additional benefit of reusing the same membrane matrices by reattaching fresh GOX and Fe+2. Functionalized Membranes Affinity Based Bioseparation HIV-TAT Protein Biocatalysis Glucose Oxidase Chemical Engineering
25	Electrochemical studies of monosubstituted squarate ligands and its transition metal and lanthanide complexes Mohamed, Nuralli January 2008 (has links) Magister Scientiae - MSc / The study introduces and puts forward Sector Policing as a model to expand community Policing and to broaden the scope of crime prevention. It also demonstrates how Sector Policing can be utilised to decentralise policing and deepen community participation. / South Africa Monosubstituted ligand electrochemistry DMF DMSO DCM glucose oxidase/glucose mediator
26	Desenvolvimento e caracterização de um biossensor bienzimático imobilizado sobre monocamadas auto-organizadas para determinação de açúcares em alimentos / Development and characterization of the byenzimatic biosensor immobilized on self assembled monolayers to determination of the sugars in food Andressa Galli 04 September 2009 (has links) Este trabalho descreve a preparação, a caracterização e o uso de um biossensor bienzimático confeccionado com as enzimas glicose oxidase e frutose dehidrogenase imobilizadas em camadas auto-organizadas ou self-assembled monolayers (SAMs) de cistamina para a quantificação de açúcares em alimentos. Após o preparo do eletrodo de ouro com a SAM de cistamina, biossensores foram construídos e para obtenção de melhores respostas, condições foram otimizadas, tais como: concentração do mediador tetratiafulvaleno (TTF), porcentagem de glutaraldeído, temperatura e tempo de vida do biossensor. Com as condições estabelecidas, fez-se então, a determinação analítica da D-glicose e da D-frutose em eletrólito puro pelo método da adição de padrão e os resultados foram obtidos por voltametria cíclica e cronoamperometria. A corrente de pico de oxidação do mediador de elétrons (TTF) aumentou proporcionalmente com o aumento da concentração e não ocorreram deslocamentos nos potenciais de pico. Os limites de detecção (LD) foram encontrados por meio do desvio padrão da média aritmética de dez amperogramas do branco no potencial equivalente aos dos picos de oxidação do mediador de elétrons TTF, juntamente com o valor do coeficiente angular da curva analítica. Após a obtenção da curva analítica o biossensor foi aplicado diretamente em amostras de refrigerante dietético e não dietético, bem como em amostras de adoçantes comerciais, onde foram realizados testes comparativos da resposta dos biossensores. Para o eletrólito puro e amostras de refrigerante dietético e de adoçantes, ou seja, onde não há presença de D-glicose e D-frutose, notou-se a ausência de corrente de pico, enquanto que para as amostras de refrigerante não dietético, houve um valor significativo de resposta de corrente, indicando a presença dos açúcares em estudo. Com o propósito de verificar a influência de interferentes e o efeito de matriz, foi construída uma curva analítica para a D-glicose e para a D-frutose, em amostras de refrigerante dietético e adoçantes, onde foram obtidas as menores quantidade destes açúcares. Para o refrigerante não dietético, foi determinado o valor inicial dos açúcares presentes nas amostras. Pode-se afirmar que a utilização dos biossensores baseados nas enzimas GOx e FDH mostraram-se eficientes para a determinação dos açúcares D-glicose e D-frutose nas amostras analisadas (com diferença significativa nos valores de corrente), apresentando uma resposta rápida, além da eliminação do efeito da matriz. A utilização do mediador de elétrons (TTF) possibilitou a reação em potencial próximo de zero, diminuindo o efeito de interferentes e evitando a desnaturação das enzimas. / This work describes the preparation, characterization and application of a bienzymatic biosensor based in the glucose oxidaze and fructose dehydrogenase immobilized on self-assembled monolayer of cystamine for sugar quantification in foodstuff. After the modification of the gold electrode with cystamine, the biosensors were developed and optimized for best responses. Optimization parameters were: mediator tetrathiafulvalene (TTF) concentration, glutaraldehyde percentage, temperature and life time of the biosensor. With the best conditions established, the analytical determinations of d-glucose and d-fructose in pure phosphate buffer were conducted by the standard additions method and the results obtained by cyclic voltammetry and chronoamperometry. The oxidation peak current related to the TTF voltammetric behavior raised proportionally to the increasing concentration of d-glucose or d-fructose, in a given and constant peak potential. The methodology detection limits were found using the standard deviation of ten chronoamperograms of the blank solution, in the potential value corresponding to that of TTF oxidation, and the slope of the analytical curve. After the analytical curve acquirement the biosensor was directly applied in samples of diet or non-diet softdrinks, as well as in commercial sweeteners samples, with comparative tests of the biosensor responses. For pure electrolyte and for diet foodstuff samples, i.e., were there is not expectation for d-glucose or d-fructose existence, it was detected the lack of the voltammetric peak associated with the mediator oxidation. In non-diet samples, a pronounced voltammetric peak was obtained, testifying the presence of sugar in the electrolytes under study. The matrix effect was verified by means of an analytical curve obtained for both analytes (d-glucose and d-fructose), in diet and sweeteners samples, properly spiked with known amounts of each analyte. It can be concluded that the utilization of the biosensor based in GOx and FDH showed to be efficient for d-glucose and d-fructose determinations in the analysed samples, with a fast response time and elimination of the matrix effect. The mediator promoted the electrochemical reaction to occur in potentials very close to zero, minimizing the interferences or the enzyme denaturation. camadas auto-organizadas frutose dehidrogenase glicose oxidase fructose dehidrogenase glucose oxidase self assembled monolayers
27	CONTROLLED OXIDATIVE MODIFICATION WITH GLUCOSE OXIDASE TO ENHANCE THE RHEOLOGICAL AND GELLING PROPERTIES OF MYOFIBRILLAR PROTEINS Wang, Xu 01 January 2017 (has links) This study investigated the feasibility of oxidative modification with glucose oxidase (GluOx) to enhance the rheological and gelling properties of myofibrillar protein. Differential oxidative modifications of myofibrillar protein (MP) by hydroxyl radicals generated in an enzymatic system with glucose oxidase (GluOx) in the presence of glucose/FeSO4 compared to a Fenton system (H2O2/FeSO4) were investigated. Firmer and more elastic MP gels were produced by the GluOx-oxidizing system than by the Fenton system at comparable H2O2 levels due to an altered radical reaction pathway. The study further explored the effect of GluOx-mediated oxidation on the efficacy of transglutaminase (TGase) cross-linking of MP in 0.6 M NaCl and the rheological properties of GluOx oxidation/TGase treated MP in MP–lipid emulsion composite gels. The GluOx-mediated oxidation promoted the formation of both soluble and insoluble protein aggregates via disulfide bonds and occlusions of hydrophobic groups. The subsequent TGase treatment converted protein aggregates into highly cross-linked polymers. MP–lipid emulsion composite gels formed with such polymers exhibited markedly enhanced gelling capacity: up to a 4.4-fold increase in gel firmness and a 3.5-fold increase in gel elasticity over untreated protein. Microstructural examination showed small oil droplets dispersed in a densely packed gel matrix when MP was oxidatively modified, and the TGase treatment further contributed to such packing. Comparison of the modification of MP via GluOx oxidation/TGase cross-linking pathway under different salt concentrations (0.3 and 0.6 M NaCl) showed different patterns of MP cross-linking, resulting in different extents of aggregation. Under low-salt condition (0.3 M NaCl), the GluOx/TGase treatment increased the gel strength to the same level as those treated with TGase in 0.6 M NaCl, suggesting a potential application of GluOx/TGase for improving gel strength in low ionic strength conditions. Finally, the application of GluOx oxidation in the development of emulsion-type sausages was studied. The GluOx oxidation/TGase cross-linking improved the textural properties (firmness, chewiness, and rupture force) of emulsion-type sausages under both salt levels (P < 0.05). Under low-salt condition (1.5% NaCl), GluOx/TGase treatment can increase the sausage binding strength to the same level as the control sample under high-salt condition (3% NaCl). The GluOx oxidation/TGase treatment shows promise to improve the textural properties of emulsified meat products. However, the significant decrease of a* value and increase of b* value indicated GluOx-induced color deterioration. Myofibrillar protein Glucose oxidase Oxidation Tranglutaminase Gelation Texture Food Chemistry Food Science
28	Conception de systèmes catalytiques hétérogènes chimioenzymatiques pour l'époxydation / Conception of heterogeneous chemioenzymatic catalysts for epoxydation Balistreri, Noémie 13 October 2016 (has links) L'objectif de ce travail est de développer un système catalytique hétérogène pour l'époxydation en utilisant directement O2 de l'air plutôt que H2O2 commercial. La stratégie adoptée a été de coupler la production in situ de H2O2, catalysée par la glucose oxydase (GOx), avec un catalyseur à base de Ti. La GOx a été immobilisée de manière covalente sur une mousse silicique mesocellulaire (MCF) amino-fonctionnalisée puis la stabilité thermique et aux solvants organiques de MCF-NH2-GOx a été étudiée. L'approche visant à ancrer Ti puis la GOx sur le même support n’a pas abouti à un catalyseur tandem efficace du fait d'un recouvrement de Ti par –NH2. L’hydrophilie de MCF apparaît, de plus, défavoriser l'oxydation d'alcènes organosolubles. Une option a consisté à utiliser la zéolithe TS-1 hydrophobe et réputée fonctionner en milieu aqueux mais dont les micropores ne peuvent loger la GOx. Cette dernière, associée à MCF-NH2-GOx en mélange mécanique, s’est montrée performante pour l'oxydation du cyclohexène dans MeOH/tampon acétate 50:50 à 35°C (rendement de 50% en époxyde et ses dérivés). D’encore meilleurs résultats ont été obtenus pour le prop-2-ène-1-ol en milieu aqueux à 40°C (rendement de 87% en glycérol). L’attaque basique de TS-1 crée une porosité suffisante pour loger la GOx, mais endommage son activité. En revanche, le recouvrement de MCF par un film de TS-1 a eu un effet bénéfique sur l’oxydation du prop-2-ène-1-ol dans l’eau par H2O2. Enfin, la porphyrine Mn-TCPP s’est montrée efficace comme catalyseur d'oxydation en tandem avec la GOx en solution mais, en cas d’immobilisation sur le support silicique MCF, la formation d’un précipité inhibe son activité. / The objective of this work was to develop an heterogeneous catalyst system supplied by dioxygen, rather than commercial H2O2, in order to carry out epoxidation reactions. Our strategy was to couple the in situ production of H2O2, catalyzed by glucose oxidase (GOx), with a Ti-based catalyst. The enzyme was covalently grafted onto a silicic mesocellular foam (MCF) functionalized by aminopropyle groups, then the thermal stability and behavior in organic solvents of the resulting material were investigated. The approach aiming at anchoring Ti, then GOx on the same support did not result in an effective tandem catalyst because of a too high –NH2 surface coverage. Hydrophilicity of MCF makes the oxidation of organosoluble alkenes unefficient. An alternative approach consisted in using the hydrophobic TS-1 zeolite known to operate in aqueous medium but whose micropores do not allow GOx hosting. However, TS-1 combined in a mechanical mixture with GOX immobilized on MCF turned out to be effective for the oxidation of cyclohexene in MeOH/acetate buffer 50:50 at 35°C (50% yield of epoxide and its derivatives). Even better performances were obtained for prop-2-ene-1-ol oxidation in aqueous medium at 40°C (87 % yield of glycerol). The basic attack of TS-1 has created mesoporosity to host GOx but damaged active Ti sites. On the other hand, TS-1 coated MCF appeared to be a good option having a beneficial effect on the oxidation of prop-2-en-1-ol in water by H2O2. Finally, a manganese porphyrin, Mn-TCPP, was also tested successfully as alkene oxidation catalyst in combination with GOx but, in case of immobilization, the presence of the silicate support lead to a deactivated catalyst. Matériau mésoporeux Fonctionnalisation Glucose oxydase Immobilisation Époxydation des alcènes Catalyse tandem Epoxidation Immobilization Glucose oxidase 541.3
29	Studies On Multiphase And Multienzymatic Oxidation Of Glucose Prasad, M Rajendra 07 1900 (has links) (PDF) No description available. Glucose - Oxidation Oxidising Agents Glucose Oxidase Glucose Oxidation Catalase Organic Chemistry
30	Evaluation of Zinc Oxide Nano-Microtetrapods for Biomolecule Sensing Applications Zhao, Wei January 2015 (has links) Zinc oxide (ZnO) is a well-known II-VI semiconductor material that has gained renewed interest in the past decade due to the developments of growth technologies and the availability of high-quality ZnO bulk single crystals. Owing to a wide direct band gap (3.37 eV), large exciton binding energy (60 meV), and high electron mobility (440 cm2 V-1 s-1), ZnO has been used for applications including actuators, optoelectronics, and sensors. ZnO nanoparticles can be synthesized in a broad variety of morphologies, such as nanotetrapods, nanotubes, and nanowires. Among these nanostructures, the tetrapods have attracted significant attention due to their unique morphology consisting of four legs connected together in a tetrahedral symmetry. Recently, it has been reported that nano-microstructured ZnO tetrapods (ZnO-Ts) can be synthesized by flame transport synthesis (FTS) in a rapid and up-scalable approach. Compared to conventional ZnO nanoparticles, the nano-microstructured ZnO-Ts can reduce cellular uptake, while still exhibiting specific nanomaterial properties due to the nanoscale tips. Moreover, the anisotropic ZnO-Ts have the advantages of multiple electron transfer paths, chemical stability, and biocompatibility, which make the ZnO-Ts promising candidates for biomolecule sensing applications. This work herein reports a systematical study on the structural, optical and electrochemical properties of the ZnO-Ts, which were synthesized by FTS using precursor Zn microparticles. The morphology of the ZnO-Ts was confirmed by scanning electron microscopy (SEM) as joint structures of four single crystalline legs, of which the diameter of each leg is 0.7-2.2 μm in average from the tip to the stem. The ZnO-Ts were dispersed in glucose solutions to study the photoluminescence as well as photocatalytic activity in a mimicked biological environment. The photoluminescence (PL) intensity in the ultraviolet (UV) region decreased with linear dependence on the glucose concentration up to 4 mM. The ZnO-Ts were also attached with glucose oxidase (GOx) and over coated with Nafion® to form the active media for electrochemical glucose sensing. The active layers were confirmed by Fourier transform infrared spectroscopy (FT-IR). Furthermore, the current response of the active layers to glucose was studied by cyclic voltammetry (CV) in various glucose concentration conditions. Stable current response to glucose was detected with linear dependence on the glucose concentration up to 12 mM, which confirms the potential of ZnO-Ts for biomolecule sensing applications. zinc oxide tetrapods nano-microstructure glucose oxidase glucose sensor Nano Technology Nanoteknik

Search results