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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
31

Development of a ZnO nanowire-array biosensor for the detection and quantification of immunoglobulins

Neveling, Deon Pieter 12 1900 (has links)
Thesis (MSc)--Stellenbosch University, 2013. / ENGLISH ABSTRACT: The aim of this study was to develop a ZnO nanowire-array biosensor that would detect immunoglobulins and record changes in the concentration of an antibody. Early detection of disease-causing agents is essential for an early response. In contrast to conventional methods, biosensors may detect disease-associated agents much faster and more accurate, which holds specific benefits to rural communities. The development of such a biosensor would be favourable for diagnostics in underprivileged communities without infrastructure. The hypothesis was that binding of antibodies to the surface of ZnO nanowires would result in the generation of a piezoelectric potential that, when channelled through a Schottky barrier, would produce a constant voltage reading. Piezoelectricty would be generated due to the bending of the nanowires, or tensile stress applied to the nanowires due to binding of the antibodies. The performance of such a device largely depends on the methods used to construct the ZnO nanowires and methods used to funtionalize the sensor surface. The biggest challenge was thus to chemically modify the self-assembled monolayers (SAMs) and create intermediate monolayers that would react to primary amino groups of lysozyme and form a covalent amide bond. Lysozyme was selected as model antigen, since its structure and reaction with antibodies has been well studied. Alkanethiol and dialkyl disulphides were used to form SAMs. Different SAMs were compared to select the absorbate that would bind the highest concentration of lysozyme. Lysozyme was best immobilized onto Au film layers in the presence of SAM 3-mercaptopropionic acid. Weakest immobilization was in the presence of combined SAM 11-mercaptoundecanoic acid/1-nonanethiol. The sensitivity of the constructed ZnO nanowire biosensor was tested in vitro, in the presence of different concentrations of lysozyme antibodies. An increase in the dimension of the ZnO seed layer led to an increase in the mean diameter of the ZnO seed grains, and subsequently an increase in the mean diameter of the synthesized ZnO nanowires. Deposition of the ZnO seed layer, using the RF cylindrical magnetron sputtering technique, improved the c-axis alignment of the nanowires and produced nanowires with similar dimensions. However, deposition of the ZnO seed layer using the sol-gel spin coating technique, produced nanowires with irregular c-axis alignments and irregular diameters. An increase in the Au film thickness led to a decrease in the mean diameter of the synthesized ZnO nanowires and worsening of the c-axis alignment. In contrast to single crystalline Au (111) film layers, polycrystalline Au layers increased the mean diameter of the synthesized nanowires. The crystal orientation of the Au film layer had no effect on the c-axis alignment. Increased voltage readings were recorded with an increase in antibody binding, indicating that the ZnO nanosensor may be used to record changes in immunoglobulin levels. Antibody concentrations ranging from 10 ng/ml to 20 μg/ml were sensed. This is the first study showing that ZnO nanowires, conformed into piezoelectric transducers, may be used in the detection of antibodies. The current size of the chip with ZnO nanowires is approximately 1 cm², which is too big to incorporate into a compact monitoring device. Apart from the challenge to produce smaller nanowire-arrays, highly sensitive sensors and miniature amplifiers will have to be developed to increase the strength of the signals generated by the nanowires. The biosensor will also have to be optimised to detect a variety of immunoglobulins. / AFRIKAANSE OPSOMMING: Die doel van hierdie studie was om ‘n ZnO nanodraad biosensor te ontwikkel wat immunoglobuliene kan opspoor en veranderinge in konsentrasies van die teenliggaampies sal reflekteer. Vroë deteksie van siekte veroorsaakende agente is belangrik vir n vroeg tydige respons. In teenstelling tot konvensionele metodes, kan biosensors siekte veroorsaakende agente vining en akkuraat opspoor, wat veral voordele vir gemeenskappe in landelike gebiede inhou. Die hipotese was dat binding van teenliggaampies aan die ZnO nanodrade ‘n piëzo-elektriese potensiaal sal skep, wat dan ‘n konstante leesbare spanningspotensiaal sal lewer nadat dit deur ‘n Schottky versperring gestuur is. Piëzo-elektrisiteit word gegenereer deur die buiging van die nanodrade, of deur spanning wat op die nanodrade geplaas word deur binding van die teenliggaampies. Die sukses van die ontwerp hang grootliks af van die metode wat gebruik word om die ZnO nanodrade te konstrueer en metodes wat gebruik word om die sensor oppervlak te funksionaliseer. Die grootste uitdaging was dus om die monolae wat outomaties saam groepeer (SAMs) chemies so te verander dat intermediêre monolae vorm wat aan primêre aminogroepe van lisosiem bind ten einde kovalente amied-bindings te vorm. Lisosiem is as model antigeen geselekteer omdat die struktuur en reaksie daarvan met teenliggaampies reeds goed bestudeer is. Alkaantiol en di-alkiel disulfied is gebruik om SAMs te vorm. ‘n Verskeidenheid SAMs is vergelyk ten einde die anker te selekteer waaraan die hoogste konsentrasie lisosiem sal bind. Lisosiem is die effektiefste aan Au film lae ge-immobiliseer in die teenwoordigheid van SAM 3-merkapto-propanoësuur. Die swakste immobilisasie is in die teenwoordigheid van kombineerde SAM 11-merkapto-dekanoësuur/1-nanotiol waargeneem. Die sensitiwiteit van die ZnO nanodrade is in vitro getoets, in die teenwoordigheid van verskillende konsentrasies van lisosiem teenliggaampies. ‘n Toename in die dimensie van die ZnO grondlaag het die gemiddelde deursnit van die ZnO grein verhoog en so ook die gemiddelde deursnit van die gesintetiseerde ZnO nanodrade. Toediening van die ZnO grondlaag deur gebruik te maak van die RF silindriese mikrogolf-verstuiwings tegniek het die orientasie van die c-aslyn van die nanodrade verbeter. Toediening met die sol-gel draai-bedekkings tegniek het ‘n onreëlmatige orientasie van die c-aslyn teweeg gebring, asook ‘n variasie in die afmetings van die nanodrade. ‘n Toename in die Au laag het ‘n afname in die gemiddelde afmetings van die nanodrade en ook ‘n onreelmatige oriëntasie van die c-aslyn veroorsaak. In teenstelling met enkel-kristallyne Au (111) het poli-kristallyne Au lagies ‘n toename in die gemiddelde deursnit van die nanodrade veroorsaak. Die kristal-oriëntasie van die Au laag het geen effek op die belyning van die nanodrade gehad nie. Die spanningspotensiaal het verhoog met ‘n toename in teenliggaampie binding. Hiervolgens kan die ZnO nanosensor gebruik word om veranderinge in immunoglobulien vlakke te monitor. Teenliggaampie konsentrasies wat wissel van 10 ng/ml tot 20 μg/ml is opgespoor. Hierdie is die eerste studie wat toon dat ZnO nanodrade, omskep tot piëzo-elektriese transduseerders, gebruik kan word in die opsporing van teenliggaampies. Die grootte van die skyfie met die ZnO nanodrade is tans ongeveer 1 cm² en is te groot om in ‘n kompakte biosensor in te bou. Benewens die uitdaging om kleiner nanodraad skyfies te ontwikkel, sal hoogs sensitiewe sensors en seinversterkers ontwikkel moet word om die sein afkomstig van die nanodrade te versterk. Die biosensor sal ook ge-optimiseer moet word om ‘n verskeidenheid immunoglobuliene op te spoor.
32

The Preliminary Study on the Role of 1-Hexene Monooxygenase in Delayed Fruit Ripening by Rhodococcus rhodochrous DAP 96253

Jiang, Wenxin 09 August 2016 (has links)
Rhodococcus rhodochrous DAP 96253, a well-known industrial bacterium, had various 1-hexene monooxygenase (1-HMO) activities when grown on YEMEA plates supplemented with eight different carbohydrates. Besides, 1-HMO exhibited different storage temperature preferences. Lactose could induce the highest 1-HMO activity in R. rhodochrous DAP 96253 while the cells showed the lowest 1-HMO activity when trehalose was the supplement. The 1-HMO activity of R. rhodochrous DAP 96253 was not maintained when stored at 37°C as well as at 4°C and 25°C. Trehalose-induced 1-HMO activity of R. rhodochrous DAP 96253 was more stable from Day 0 to Day 21 at all these three temperatures, compared with the other seven carbohydrates. Immobilization of enzymes can maintain enzyme activity longer, offer easier enzyme storage conditions and make some enzymes reusable, much research has been done in this area. In this study, R. rhodochrous DAP 96253, grown on YEMEA plates supplemented by glucose and urea, was investigated using whole bananas as the inducer of 1-HMO activity and different immobilization methods to maintain this enzyme activity. It was shown that calcium-alginate polyvinyl alcohol (PVA) beads could maintain 1-HMO activity of R. rhodochrous DAP 96253 more stable than calcium-alginate beads. Whole bananas exhibited very obvious effects of inducing 1-HMO activity of R. rhodochrous DAP 96253. A number of recent studies have clearly demonstrated that induced cells of R. rhodochrous DAP 96253 can prolong the shelf-life of post-harvested fruits. With USDA estimates of 40% of all harvested produce in the US not being consumed because of loss of quality, the ability to extend the period of ripeness of produce has great potential to improve the quality of nutrition. Modification or degradation of those signals (primary and secondary) associated with ripening in fruit or the perception of those signals represents a potential mode of action for delayed ripening by induced cells of R. rhodochrous DAP 96253. Ethylene and cyanide are the two primary signals in ripening. In this study, the role of 1-HMO from induced cells was investigated by time-course experiments focusing on 1-HMO activity and stability. In addition, fruit volatile organic compounds (VOCs) were detected and compared by GC-FID and GC/MS over the course of fruit ripening. The results show a correlation between 1-HMO activity and stability in delayed fruit ripening. It was further demonstrated that the presence of secondary signal fruit VOCs enhanced 1-HMO activity. Aromatic profiles of treated fruits, by GC-FID and GC/MS, show a consistent picture of VOCs associated with earlier fruit ripening stages.
33

Characterization of Immobilized Aqueous Quantum Dots: Efforts in High-Resolution Microscopy

Young, Amber Lynn January 2011 (has links)
Semiconductor quantum dots (QDs), particles several nanometers in diameter, exhibit a range of interesting properties that arise as a result of quantum confinement. Among these characteristics is photoluminescence, and unlike traditional fluorophores, the fluorescence emission of QDs is characterized by broad absorption and narrow emission that is a function of the particle diameter. This allows high spatial resolution to be achieved using spectral discrimination of closely spaced QDs.We propose applying QD fluorescence as a tool to sense the local environment of the QD to achieve wide-field sensing at high-resolution. Many factors influence QD fluorescence from the growth parameters and choice of ligand to the local environment of the QD post-fabrication. Nano-materials in the local QD environment influence the spectral or temporal characteristics of the QD fluorescence and detecting these changes enables identification of the location and motion of these nanoparticles with resolution on the order of a few nanometers.We have fabricated aqueous colloidal cadmium telluride QDs, experimenting with the choice of thiol-based ligand to influence the chemistry in post-processing and application. A wide range of tools have been used to characterize the spectral and physical properties of the QDs. We have successfully immobilized QDs on a variety of substrates including glass coverslips, silicon and indium tin oxide coated glass. Immobilization is achieved with even and consistent distributions of QDs on the substrate by using self-assembly of the colloidal particles onto substrates functionalized with N1-(3-Trimethoxysilylpropyl)diethylenetriamine (DETA) silane.Using fluorescence microscopy we have successfully demonstrated the detection of interactions between QDs and other nano-materials including green fluorescent protein and gold seed particles, demonstrating that QDs may, in principle, be used in a wide field microscopy technique to sense nano-materials with high resolution.
34

Electrodes catalytiques à base d’enzymes pour le développement de biopiles alcool/oxygène microfluidiques. / Catalytic electrodes based on enzymes for the development of microfluidic alcohol/oxygen biofuel cells.

Techer, Vincent 19 December 2013 (has links)
Les biopiles enzymatiques sont considérés comme des systèmes potentiellement utilisables pour la production d'énergie renouvelable dans des marchés niches. Une biopile est constituée de deux électrodes associées à des enzymes, catalyseurs biologiques, qui permettent la production d'énergie électrique à partir de réactions chimiques d'oxydoréduction. Ce travail présente la réalisation d'une biopile alcool/oxygène, au sein de laquelle l'alcool est oxydé à l'anode par l'alcool déshydrogénase alors que l'oxygène moléculaire est réduit en eau à la cathode par l'enzyme laccase, en présence de médiateurs spécifiques. L'objectif de ce travail a été tout d'abord de développer des bioélectrodes avec des enzymes immobilisées de manière à minimiser la quantité de biocatalyseur et augmenter sa stabilité. Dans un second temps, l'assemblage de biocathodes et de bioanodes a permis de fabriquer des biopiles à alcool macroscopique et microfluidique. Différentes poudres de carbone combinées à des polymères ont été utilisées pour immobiliser les enzymes et les médiateurs par encapsulation selon diverses configurations. Des analyses électrochimiques ont permis de mettre en évidence l'influence importante de certains paramètres comme la nature du carbone et du polymère, le pH et la température sur les performances des bioélectrodes. Une fois assemblées dans les configurations classique ou microfluidique, ces bioélectrodes ont conduit à des systèmes électrochimiques de génération d'énergie délivrant une densité de puissance maximale de 300μW/cm2 à 0,61V pour la biopile macroscopique et de 45μW/cm2 à 0,5V pour le système microfluidique. / Enzymatic biofuel cells (BFC) are systems of great interest for the production of renewable energy in niche markets. A BFC consists of two electrodes associated with enzymes as catalysts allowing energy production from oxydoreduction reactions. This work is devoted to the development of an alcohol/oxygen BFC for which alcohol is oxidized at the anode by alcohol dehydrogenase while molecular oxygen is reduced to water at the cathode by laccase, in the presence of specific mediators. The objective of this work was first to develop bioelectrodes with immobilized enzymes in order to minimize the amount of biocatalyst and increase its stability. In a second step, biocathodes and bioanodes were assembled to make macroscopic and microfluidic alcohol BFCs. Various carbon powders combined to polymers were used to immobilize enzymes and mediators in various configurations by entrapment. Electrochemical analysis have highlighted the significant influence of certain parameters like the nature of polymer and carbon, the pH or the temperature on the bioelectrodes performances. Once assembled in classical or microfluidic configurations, these bioelectrode led to electrochemical energy generation systems delivering a maximum power density of 300μW/cm2 at 0,61V for the macroscopic BFC and 45μW/cm2 at 0,5V for the microfluidic system.
35

Imobilização de pepsina em membranas liofilizadas de quitosana e O-carboximetilquitosana / Pepsin immobilization into lyophilized chitosan and O-carboxymethilchitosan membranes

Mello, Karine Gargioni Pereira Correa de 23 November 2009 (has links)
Enzimas são proteínas utilizadas em processos tecnológicos diversos. Estas enzimas dependendo do tipo e grau de pureza são geralmente caras. Comumente as enzimas exigem controle contínuo do processo no que se refere à temperatura, pH, agitação, entre outros, e após o uso são descartadas, o que torna o custo do processo mais elevado. Em decorrência disto, a imobilização de enzimas em suportes insolúveis e inertes, vem sendo proposta com resultados promissores de manutenção e até mesmo aumento da atividade enzimática, resistência mecânica, térmica e de pH, bem como por apresentar maior facilidade de remoção da enzima do sistema e possibilitar sua reutilização. Por causa disto, diferentes tipos de suportes vêem sendo estudados, dentre estes, os materiais poliméricos, tem recebido atenção especial. A quitosana é um polímero natural, biocompatível, biodegradável e atóxico. É obtida de fontes renováveis provenientes do descarte de cascas de crustáceos da indústria de alimentos, o que constitui um fator ambiental importante atualmente. Neste trabalho a enzima pepsina foi imobilizada em membranas liofilizadas de quitosana e O-carboximetilquitosana reticuladas ou não com glutaraldeído. A pepsina imobilizada na membrana de quitosana reticulada com glutaraldeído manteve sua atividade enzimática e o suporte apresentou propriedades físico-químicas de resistência a solubilização em pH ácido, o qual é necessário para atividade da pepsina. O processo de liofilização preservou a estrutura do suporte e não comprometeu a atividade enzimática. Demonstrando que o processo de liofilização é viável para secagem e incorporação de enzimas. / Enzymes are proteins used in a wide variety of biotechnological processes. Commonly, enzymes require stringent conditions, such as a particular pH, temperature, stirring, etc. In chemical and biochemical reactions, purified enzymes can be rather costly and additionally, must be discarded after each use, which is still less economical. As a result of this, enzyme immobilization on insoluble and inert supports has been studied as a manner to overcome these problems and optimize enzymes use. Promising results of greater immobilized enzyme activity and stability over a broader range of pH and temperature have been reported. As well, immobilized enzymes can be easily removed from the system and reused. Various materials have been employed as enzymes supports, among then, the polymers have received special attention. Chitosan is a natural polymer that presents biocompatibility, biodegradability and nontoxicity. Chitosan is obtained from crustacean shell wastes discarded by the food industry, and recover this material constitutes an important environmental factor nowadays. In this work the enzyme pepsin was immobilized on freezedried chitosan and O-Carboxymethylchitosan membranes crosslinked or not with glutaraldehyde. Pepsin immobilized on chitosan membrane crosslinked with glutaraldehyde maintained its enzymatic activity and the polymer support provided physicochemical properties such resistance to dissolution in acid pH. Acid pH is required for pepsin activity. The freeze-drying process preserved the support structure and did not compromise the enzymatic activity. Demonstrating that, freeze drying process, is viable for drying and enzymes incorporation.
36

Membranas eletroativas nanoestruturadas: estudo de transporte de carga e imobilização enzimática / Electroactive nanostructured membranes

Crespilho, Frank Nelson 26 February 2007 (has links)
Esta tese aborda quatro tópicos fundamentais para o desenvolvimento e aplicação de membranas eletroativas nanoestruturadas (MENs): (i) síntese e caracterização de nanopartículas (Nps) de prata, ouro e platina encapsuladas em moléculas de dendrímero poliamidoamina geração 4 (PAMAM); (ii) preparação de filmes automontados contendo PAMAM e Nps de ouro (PAMAM-Au); (iii) preparação de MENs utilizando sistema core-shell PAMAM-Au@Me, onde Me é um mediador redox; (iv) imobilização enzimática em MENs e estudos biocatalíticos associados a processos eletroquímicos. As Nps foram caracterizadas observando-se a banda plasmônica em espectros na região do UV-Vis. Imagens de microscopia eletrônica de transmissão revelaram que PAMAM-Au e PAMAM-Pt possuem morfologias esféricas, enquanto o PAMAM-Ag forma grandes cristais com estruturas fractais. Estruturas cúbicas de face centrada caracterizaram os cristais formados de Au e Pt, sendo possível estimar os diâmetros (3,0 nm) das Nps pela equação de Scherrer em difratogramas de raios X, confirmados posteriormente por microscopia eletrônica por transmissão (TEM). Um indício de estabilização por encapsulamento do híbrido PAMAM-Au foi obtido de espectros de infravermelho (FTIR), a partir de modificações nas bandas das amidas. A cinética de reação para formação de PAMAM-Au também foi estudada. Filmes de PVS/PAMAM-Au (onde PVS é o poli(ácidovinilssulfônico)) foram preparados com 5 minutos de imersão, com a mesma quantidade de material sendo adsorvida em cada camada, segundo medidas de espectroscopia UV-Vis e voltametria cíclica (CV). No caso do eletrodo ITO-(PVS/PAMAM-Au), saltos de elétrons foram considerados o mecanismo de transporte de carga ao longo do filme. Um novo sistema core-shell Au@PB foi preparado, formando um sistema ITO-(PVS/PAMAM-Au)6@PB, em que a eletrodeposição de PB (azul da Prússia) foi monitorada medindo-se as correntes faradaicas durante os ciclos potenciodinâmicos. Outros mediadores de hexacianoferratos de metais de transição (Fe, Ni, Co e Cu) foram obtidos sobre eletrodos de ITO-(PVS/PAMAM-Au). De resultados de espectroscopia de impedância eletroquímica (EIS), verificou-se que a resistência de transporte de carga decresce na sequência CuHCF > FeHCF > NiHCF > CoHCF e todos os eletrodos apresentaram atividade catalítica para o peróxido de hidrogênio. Uma nova configuração de eletrodo, ITO-(PVS/PAMAM-Au)3@CoHCF-GOx, pôde ser aplicada como dispositivo enzimático, com a glicose oxidase (GOx) sendo imobilizada por drop-coating na superfície do eletrodo e aplicada em experimentos de biocatálise. A glicose pôde ser detectada a 0,0 V (Ag/AgCl), com resposta linear até 100 µmol L-1 de glicose, sensibilidade de 115 nA mmol L-1, limite de detecção de 5,5 µmol L-1 e KMapp de 0,24 mmol L-1, mostrando que o sistema aqui proposto cria um ambiente propício para a enzima operar com alta atividade catalítica. / This thesis addresses four fundamental topics for producing and applying electroactive nanostructured membranes (ENMs): (i) synthesis of Au, Pt and Ag nanoparticles (Nps) using polyamidoamine (PAMAM generation 4) dendrimers as template/stabilizers; (ii) fabrication of layer-by-layer (LbL) films comprising PAMAM with AuNps (PAMAM-Au) and poly(vinylsulfonic acid) (PVS); (iii) preparation of a new core-shell system with Prussian blue (PB) around the Au nanoparticles (PAMAM-Au@PB); (iv) enzyme immobilization on ENMs and bioelectrochemistry studies. The formation of the Nps inside PAMAM was monitored by measuring the plasmonic band of NPs via UV-Vis spectroscopy. Images from transmission electron microscopy (TEM) showed well-organized Au and Pt spherical particles, with average diameter of 3 nm and narrow size distribution. In addition, X-ray diffraction of Nps enabled easy identification of the Nps atomic planes (face-centered cubic arrangements). However, PAMAMAg growth showed fractals structures. In order to confirm Au NPs encapsulation inside the PAMAM dendrimer, FTIR spectra in the transmission mode for neat PAMAM and PAMAM-Au were compared. The kinetics of formation of PAMAM-Au was studied by UV-Vis spectroscopy. The deposition of individual PAMAM-Au layers was examined in detail: the adsorption kinetics was determined by CV to be first-order and that 5 min of adsorption was sufficient for maximum coverage. Formation of PVS/PAMAM-Au multilayers showed a linear increase in anodic and cathodic peak currents, indicating that the same amount of material was adsorbed in each deposition step. Electron-hopping was inferred as the charge transport mechanism between PAMAM-Au layers. Using hexacyanoferrate (III) to probe the electrochemical reaction at the electrode surface, the charge transport in the PAMAM-Au layers was shown to be faster than for non-modified electrodes. A new system based on PAMAM-Au@PB was prepared by simple potential cycling electrodeposition after ITO-PVS/PAMAM-Au LbL film preparation. New systems are described based on ENM membranes of ITOPVS/ PAMAM-Au LbL electrodes, with a redox mediator (Me) electrodeposited around Au nanoparticles. The resulting ITO-PVS/PAMAM-Au@Me system was then characterised electrochemically using cyclic voltammetry and electrochemical impedance spectroscopy. We demonstrated that the concept of ENM can be generalized to a wider variety of redox mediators. All electrodes modified with hexacyanoferrates showed electrocatalytic activity towards hydrogen peroxide, which is promising for the preparation of nanodevices requiring redox mediators. An electrochemical enzyme device with glucose oxidase (GOx) immobilized at ITO-(PVS/PAMAM-Au)3@CoHCF ENM was developed. Using CoHCF as redox mediator, hydrogen peroxide (the enzymatic reaction product) was determined at 0.0 V (vs. SCE), with linear range up to 100 Zmol L-1 of glucose, sensitivity of 115 nA mmol L-1, detection limit of 5.5 Zmol L-1 and KM app of 0.24 mmol L-1. Such a performance indicates that this system promotes a friendly environment for enzyme immobilization.
37

Imobilização da quitosana da carapaça de siri Charybdis hellerii em filmes poliméricos a partir de sua obtenção com o uso da radiação ionizante / Detention of chitosan of crab shell of Charybdis hellerii in movies polymeric obtained from use with radiation ionizing

Ferreira, Maiara Salla 18 October 2016 (has links)
A quitosana é um polisacarídeo obtido pela desacetilação das moléculas de quitina, principal constituinte de alguns fungos e do exoesqueleto de crustáceos e insetos. Os grupos amino presentes na quitosana conferem-lhe importantes propriedades biológicas, como a biodegradação, biocompatibilidade, atividade/efeitos imunológicos e atividade antibacteriana. A desacetilação da quitina é um processo cuja conversão é agressiva, já que exige o ataque da quitina em solução de álcalis em alta concentração e à quente, com duração de 6 a 8 horas. Neste trabalho, carapaças de siri da espécie Charybdis hellerii foi fragmentada e pré-tratada para a obtenção da quitosana e cada etapa, desde o pré-tratamento do material in natura à sua conversão em quitosana, foi investigada detalhadamente. Observou-se que dose e taxa de dose não influenciaram no pré-tratamento ou na etapa de desacetilação da quitina; na dose de 20 kGy (gama ou feixe de elétrons), o processo de conversão teve duração de 60 minutos. A quitosana obtida teve baixa massa molar e grau de desacetilação comparável á quitosana padrão (SA), dependendo das condições de irradiação. Além disso, apresentou inibição da atividade bacteriana tanto livre como imobilizada em substratos poliméricos de polipropileno e de polietileno processados também por radiação ionizante. / Chitosan is a polysaccharide obtained from chitins molecule deacetylation, which is the main composition of certain fungi species and crustaceans and insects exoskeleton. The amino groups present in chitosan give it important biological properties such as biodegradability and biocompatibility, activity/immunological effects and antibacterial healing. The deacetylation of chitin is an aggressive process, which reaction processes in 6 to 8 hours under hot concentrated alkali solution. In this work, Charybdis hellerii crab shells was fragmented and pre-treated for chitosan obtention and each conversion step, from in natura material pre-treatment to final chitosan, were investigated in deteails. It was observed dose and dose rate have not influence neither pre-treatment nor chitin deacetylation steps; at 20 kGy (from gamma or electron beam sources), the conversion process was performed in 60 minutes. The obtained chitosan presented low weight and deacetylation degree compared to standard chitosan, considering specific irradiation conditions. Also, obtained chitosan presented bacterial inactivity as a free compoud as immobilized onto polymeric substrates such polypropylene and polyethylene, also processed by ionizing radiation.
38

Estudo da remoção de fenóis de soluções aquosas através da adsorção em quitosana, degradação enzimática por tirosinase e imobilização de tirosinase em matriz de quitosana / Study of the removal of phenols from aqueous solution through adsorpition by quitosan by tyrosinase enzyme degradetion and inmobilization of tyrosinase in chitosan matrix

Chavita, Alexandre Camargo 22 April 2010 (has links)
O presente trabalho apresenta o estudo de processos biotecnológicos para a remoção de fenol de soluções aquosas em regime de batelada em 3 processos distintos (A), (B) e (C) respectivamente. Sendo eles a adsorção de fenóis de soluções aquosas em Quitosana, degradação enzimática de fenóis através da tirosinase em meio aquoso e adsorção/degradação de fenóis de soluções aquosas em Quitosana contendo tirosinase imobilizada. Para isto foram estudadas as influências das variáveis temperatura, pH, concentração da Quitosana e velocidade de agitação no processo (A), temperatura, pH, concentração da tirosinase livre e velocidade de agitação no processo (B) e no processo (C), temperatura, pH, concentração da Quitosana, concentração da tirosinase imobilizada e velocidade de agitação. / This paper presents the study of biotechnology processes for the removal of pHenol from aqueous solution in batch reactor in 3 separate cases (A), (B) and (C) respectively. As they adsorption of pHenols from aqueous solutions on chitosan, enzymatic degradation of pHenols by tyrosinase in aqueous solution and adsorption / degradation of pHenols in aqueous solutions containing chitosan immobilized tyrosinase. For this we examined the influence of varying temperature, pH, concentration of chitosan and stirring speed of the process (A), temperature, pH, concentration of free tyrosinase and stirring speed of the process (B) and Case (C), temperature , pH, concentration of chitosan, concentration of tyrosinase immobilized and speed of agitation.
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Imobilização e engenharia de proteínas de glucansucrases

Graebin, Natália Guilherme January 2018 (has links)
Glucansucrases são enzimas que atuam em reações de síntese de polissacarídeos e oligossacarídeos. Para que esses biocatalisadores sejam aplicados em escala industrial, é desejável ótimas estabilidades térmica e operacional, o que pode ser alcançado com a imobilização de enzimas. Como alternativa aos suportes sólidos amplamente estudados, está a quitosana, polímero que não apresenta toxicidade e possui alta biocompatibilidade e alta afinidade com proteínas. Outra possibilidade promissora na imobilização de enzimas, é a síntese dos agregados enzimáticos entrecruzados (CLEAs), os quais apresentam alta atividade catalítica e alta estabilidade. Contudo, uma peculiaridade das glucansucrases quando produzidas em meio contendo sacarose é a camada de polímero que as envolve, e que bloqueia o acesso aos grupos reativos na superfície da proteína. No caso da expressão heteróloga das glucansucrases em Escherichia coli essa dificuldade pode ser contornada. Além disso, o uso da mutagênese sítio-dirigida pode proporcionar modificações de aminoácidos na superfície da enzima, tais como os resíduos Lys, Cys, His, com o intuito de que melhorias na imobilização sejam alcançadas. Sendo assim, na primeira etapa desse trabalho, uma extensa discussão é apresentada em relação às metodologias de imobilização de dextransucrase encontradas na literatura. A seguir, estudos referentes à imobilização da dextransucrase de Leuconostoc mesenteroides B-512 F em esferas de quitosana ativadas com glutaraldeído foram realizados. Esse imobilizado apresentou alta atividade catalítica (197 U/g) quando utilizada a carga de proteína de 400 mg/g de suporte. Além disso, observou-se que a imobilização covalente e os açúcares maltose e glicose promoveram proteção à enzima em temperaturas de 40 ºC e 50 ºC. Na etapa seguinte, a produção e a caracterização de CLEAs de dextransucrase de L. mesenteroides B-512 F foram investigados. Demonstrou-se que o tratamento com a dextranase foi essencial para a imobilização da glucansucrase e que o isopropanol foi o melhor agente precipitante. Os CLEAs apresentaram pH e temperatura ótimos de 3,0 e 60 ºC, respectivamente, enquanto que a dextransucrase imobilizada nas esferas de quitosana funcionalizada com glutaraldeído apresentaram os valores de 4,5 e 20 ºC. Ambas formas imobilizadas apresentaram boa estabilidade operacional na síntese de oligossacarídeos uma vez que após 10 ciclos, 40 % de atividade residual foi observada. Por fim, estão apresentados estudos sobre a modelagem das estruturas tridimensionais e a mutagênese sítio-dirigida das glucansucrases DSR-S vardel Δ4N and ASR C-APY del. Os modelos preditos demonstraram boa qualidade e a mutagênese sítio-dirigida não promoveu perdas significativas na atividade enzimática dos mutantes. Somente o mutante DSR_S326C mostrouse inativo. Os resultados obtidos sugerem que a imobilização da dextransucrase foi satisfatória e que cada técnica possibilita diferentes características ao imobilizado. Além disso, os imobilizados foram adequados para síntese de dextrana e oligossacarídeos. / Glucansucrases are enzymes that catalyze the synthesis of polysaccharides and oligosaccharides. In order to assure continuous processing and reuse of the biocatalyst in industrial applications, enzyme immobilization techniques are required to promote good thermal and operational stabilities. Among the several solid supports for enzyme immobilization, chitosan shows interesting properties because it is non-toxic, it is biocompatible, and it has high protein affinity. Other possibility is the production of cross-linked enzyme aggregates (CLEAs), which presents high catalytic activity and good stability. However, glucansucrases have a particularity when produced in sucrose medium, since a polymer layer surrounds the protein, blocking the access to reactive groups on the enzyme surface. To overcome this problem, it is possible to make the heterologous production of glucansucrases in Escherichia coli. Likewise, the site-directed mutagenesis may promote changes in the amino acids located on the surface to improve immobilization parameters. Therefore, this work aimed to discuss the several techniques applied for dextransucrase immobilization, and to design new immobilized biocatalysts. In a first step, it is presented a review about the distinct immobilization methodologies for dextransucrase. In a second study, an investigation about dextransucrase from Leuconostoc mesenteroides B-512 F immobilized on glutaraldehyde-activated chitosan particles was carried out. The novel immobilized biocatalyst showed 197 U/g (400 mg/g dried support) of catalytic activity. The covalent immobilization promoted protection against enzyme damages at 40 ºC and 50 ºC, whereas maltose and glucose acted as stabilizers. Furthermore, it was studied the production and characterization of CLEAs dextransucrase from L. mesenteroides B-512 F. It was demonstrated that dextranase treatment was crucial for immobilization. Isopropanol was chosen as the best precipitant agent. CLEAs presented optimal pH and temperature of 3.0 and 60 ºC, respectively, whereas it was found values of 4.5 e 20 ºC for dextransucrase immobilized on glutaraldehyde-activated chitosan particles. Both immobilized biocatalysts showed good operational stability in the oligosaccharides synthesis, exhibiting 40 % of residual activity after 10 cycles. Finally, the study concerning the homology modeling and site-directed mutagenesis of glucansucrases DSR-S vardel Δ4N and ASR C-APY del is presented. The predicted models showed good quality and it has been demonstrated that the site-directed mutagenesis did not promote significant losses in the variant enzyme activities. Only one mutant (DSR_S326C) had shown no dextransucrase activity. The results obtained in this work suggest that the immobilization of dextransucrase was satisfactory, also showing that each technique promotes different characteristics to the immobilized biocatalyst. Besides, these immobilized enzymes were feasible for the synthesis of dextran and oligosaccharides.
40

Estudo da remoção de fenóis de soluções aquosas através da adsorção em quitosana, degradação enzimática por tirosinase e imobilização de tirosinase em matriz de quitosana / Study of the removal of phenols from aqueous solution through adsorpition by quitosan by tyrosinase enzyme degradetion and inmobilization of tyrosinase in chitosan matrix

Alexandre Camargo Chavita 22 April 2010 (has links)
O presente trabalho apresenta o estudo de processos biotecnológicos para a remoção de fenol de soluções aquosas em regime de batelada em 3 processos distintos (A), (B) e (C) respectivamente. Sendo eles a adsorção de fenóis de soluções aquosas em Quitosana, degradação enzimática de fenóis através da tirosinase em meio aquoso e adsorção/degradação de fenóis de soluções aquosas em Quitosana contendo tirosinase imobilizada. Para isto foram estudadas as influências das variáveis temperatura, pH, concentração da Quitosana e velocidade de agitação no processo (A), temperatura, pH, concentração da tirosinase livre e velocidade de agitação no processo (B) e no processo (C), temperatura, pH, concentração da Quitosana, concentração da tirosinase imobilizada e velocidade de agitação. / This paper presents the study of biotechnology processes for the removal of pHenol from aqueous solution in batch reactor in 3 separate cases (A), (B) and (C) respectively. As they adsorption of pHenols from aqueous solutions on chitosan, enzymatic degradation of pHenols by tyrosinase in aqueous solution and adsorption / degradation of pHenols in aqueous solutions containing chitosan immobilized tyrosinase. For this we examined the influence of varying temperature, pH, concentration of chitosan and stirring speed of the process (A), temperature, pH, concentration of free tyrosinase and stirring speed of the process (B) and Case (C), temperature , pH, concentration of chitosan, concentration of tyrosinase immobilized and speed of agitation.

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