Avalia??o do estresse oxidativo induzido por superf?cies de tit?nio

Queiroz, Jana Dara Freires de

29 November 2011

Made available in DSpace on 2014-12-17T14:03:39Z (GMT). No. of bitstreams: 1 JanaDFQ_DISSERT.pdf: 1850683 bytes, checksum: e5171a51c7f0d0df9cc94a873195a0f7 (MD5) Previous issue date: 2011-11-29 / Commercially pure Titanium (cp Ti) is a material largely used in orthopedic and dental implants due to its biocompatibility properties. Changes in the surface of cp Ti can determine the functional response of the cells such as facilitating implant fixation and stabilization, and increased roughness of the surface has been shown to improve adhesion and cellular proliferation. Various surface modification methods have been developed to increase roughness, such as mechanical, chemical, electrochemical and plasma treatment. An argon plasma treatment generates a surface that has good mechanical proprieties without chemical composition modification. Besides the topography, biological responses to the implant contribute significantly to its success. Oxidative stress induced by the biomaterials is considered one of the major causes of implant failure. For this reason the oxidative potential of titanium surfaces subjected to plasma treatment was evaluated on this work. CHO-k1 cells were cultivated on smooth or roughed Ti disks, and after three days, the redox balance was investigated measuring reactive oxygen species (ROS) generation, total antioxidant capacity and biomarkers of ROS attack. The results showed cells grown on titanium surfaces are subjected to intracellular oxidative stress due to hydrogen peroxide generation. Titanium discs subjected to the plasma treatment induced less oxidative stress than the untreated ones, which resulted in improved cellular ability. Our data suggest that plasma treated titanium may be a more biocompatible biomaterial. / O Tit?nio comercialmente puro (cpTi) ? amplamente utilizado em implantes ortop?dicos e dentais gra?as ?s suas propriedades f?sico-qu?micas. Mudan?as na superf?cie do cpTi podem determinar respostas funcionais nas c?lulas influenciando a fixa??o e estabiliza??o do implante. Muitos m?todos de modifica??o na superf?cie podem ser aplicados para aumentar a rugosidade como, por exemplo, tratamentos mec?nicos, qu?micos, eletroqu?micos e a plasma. Este ?ltimo, quando realizado em atmosfera de arg?nio gera uma superf?cie rugosa com boas propriedades mec?nicas sem alterar a composi??o qu?mica do material. Superf?cies rugosas geralmente s?o mais biocompat?veis que as lisas, pois esse tipo de topografia facilita os processos de ades?o e prolifera??o celular. Al?m da topografia, as rea??es biol?gicas desencadeadas em resposta ao implante contribuem de forma significativa para o sucesso do mesmo. Dentre estas rea??es, o estresse oxidativo tem sido apontado como um dos principais respons?veis por falhas na implanta??o. Diante do exposto, o potencial oxidativo das superf?cies de tit?nio tratadas e n?o tratadas a plasma em atmosfera de arg?nio foi avaliado neste trabalho. Para tanto, c?lulas CHOk1 foram cultivadas sobre as superf?cies de tit?nio (tratadas e n?o tratadas). Ap?s tr?s dias de cultivo o potencial oxidativo foi investigado por meio da quantifica??o de esp?cies reativas, an?lise da capacidade antioxidante e an?lise de biomarcadores de dano oxidativo (lipoperoxida??o, carbonila??o prot?ica e oxida??o das bases do DNA). Os resultados obtidos indicam que ambas as superf?cies de tit?nio induzem estresse oxidativo, sendo o per?xido de hidrog?nio a principal esp?cie envolvida. O tratamento a plasma reduziu os danos oxidativos e promoveu melhora na habilidade celular em responder ao estresse oxidativo. Deste modo, a modifica??o da superf?cie de tit?nio atrav?s do tratamento a plasma pode ser uma alternativa para a obten??o de um material com melhor biocompatibilidade. / 2020-01-01

Biomaterial

Tit?nio

Plasma de arg?nio

Estresse oxidativo.

Biomaterial

Titanium

Plasma treatment

Oxidative stress.

CNPQ::CIENCIAS BIOLOGICAS::BIOQUIMICA

Micro-injection moulded microneedles for drug delivery

Nair, Karthik Jayan

January 2014

The emergence of microneedle (MN) technologies offers a route for a pain free, straightforward and efficient way of transdermal drug delivery, but technological barriers still exist which pose significant challenges for manufacture of MN systems with high volume outputs at low cost. The main aim of this research was to develop new ways for MN manufacture primarily using micro-injection moulding processes with high performance engineering thermoplastics. During the moulding process these polymeric melts will be subjected to extreme stress and temperature gradients and detailed material characterisation combined with in-line monitoring is desirable to optimise the moulding parameters and will help in achieving sharp microneedles with acceptable quality. Hence high shear rheology of these selected materials was performed at wall shear rates carried out in excess of 107 s-1 over a range of temperatures to predict the flow behaviour of polymer melts at such high shear strain rates. This information was fed into injection moulding simulation software tools (Moldflow) to assist the MN production process design. The optimal design was then used to produce a full 3D solid model of the injection mould and mould insert. Furthermore various design of experiments were conducted considering input parameters such as injection pressure, injection speed, melt temperature, filling time and mould cavity temperature. Response variables including product quality and data acquired from the cavity pressure and temperature transducers were used to optimise the manufacturing process. The moulded MNs were geometrically assessed using a range of characterisation techniques such as atomic force microscopy, confocal microscopy and scanning electron microscopy. An attempt to make hollow MNs was performed and encountered many challenges like partial cavity filling and part ejection during processing. Studies were carried out to understand the problem and identified the major problem was in tool design and improvements to the moulding tool design were recommended. Plasma treatment and mechanical abrasion were employed to increase the surface energy of the moulded polymer surfaces with the aim of enhancing protein adsorption. Sample surface structures before and after treatment were studied using AFM and surface energies have been obtained using contact angle measurement and calculated using Owens-Wendt theory. Adsorption performance of bovine serum albumin and release kinetics for each sample set was assessed using a Franz diffusion cell. Results indicate that plasma treatment significantly increases the surface energy and roughness resulting in better adsorption and release of BSA. To assist design-optimisation and to assess performance, a greater understanding of MN penetration behaviour is required. Contact stiffness, failure strength and creep behaviour were measured during compression tests of MN against a steel surface, and in-vitro penetration of MNs into porcine skin. The MN penetration process into porcine skin was imaged using optical coherence tomography. Finally, a finite element model of skin was established to understand the effect of tip geometry on penetration. The output of findings from this research will provide proof of concept level development and understanding of mechanisms of MN penetration and failure, facilitating design improvements for micro-injection moulded polymeric MNs.

615.1

Obstacles and Solutions to Studying Functional Adhesives Using Vibrational Sum-Frequency Generation Spectroscopy

Andersen, Angela Renee

01 December 2013

Important aspects of adhesion occur at interfaces, including structures that may be different from those in the bulk materials. However, probing the orientation of molecules in functional adhesives poses a significant challenge because adhesive molecules are always located at a buried interface. The limited penetration depth of surface-specific analysis prohibits the study of buried interfaces using those techniques. The large quantity of bulk molecules relative to the adhesive molecules interacting at the interface results in the bulk signal swamping out adhesive signal in bulk analysis techniques. An interface-specific technique is required to study functional adhesives. One such technique that has shown promise in recent years is Vibrational sum frequency generation (VSFG) spectroscopy. This technique is useful for studying interactions that occur at surfaces and interfaces because it selectively probes regions of broken inversion symmetry. Despite the ability of VSFG to isolate signal from a buried interface, a non-resonant signal that is produced simultaneously with the resonant signal corrupts the vibrational data of interest and greatly impedes reliable analysis of VSFG spectra. Over the last several years, researchers have experimentally removed non-resonant signal by delaying the upconverting pulse with respect to the initial excitation. Obtaining reliable results from VSFG data depends upon complete removal of non-resonant signal. However, complete removal of non-resonant signal presents a challenge because it can be present in spectra even when the indicators of non-resonant signal are absent. By taking advantage of polarization selection rules for VSFG and the differing symmetry of an azimuthally isotropic film and an azimuthally non-isotropic substrate, spectra containing non-resonant signal can be easily identified. These and other advances in VSFG methodology have enabled the study of surface and interfacial systems of interest. In a study of the effects of plasma treatment on polystyrene thin films, plasma exposure was found to affect not only the free surface but also portions of the sub-surface polymer, challenging previous assumptions that plasma effects are constrained to the free surfaces of materials. The next step is to use VSFG to study functional adhesives under known amounts of applied stress. An apparatus is in place to simultaneously collect VSFG spectra during mechanical testing of a functional adhesive, and in preliminary studies, an increase in VSFG non-resonant signal has been observed when a pulling force is applied to the adhesive bond.

adhesion

plasma treatment

surface spectroscopy

sum-frequency generation spectroscopy

nonlinear spectroscopy

polymers

strength testing

spin-coating

signal processing

Biochemistry

Chemistry

Durability and Adhesion of a Model Epoxy Adhesive Bonded to Modified Silicon Substrates

Xu, Dingying

07 July 2004

The adhesion and durability of model epoxy/silane/SiO2/Si bonded systems were investigated under various conditions, including the type of surface preparation, pH of the environmental media, temperature, cyclic thermal stress, and external applied stress. The fundamental debond mechanism was studied for bonded systems exposed to selected environments. The bond failure mode was characterized by examining the failed bond surfaces using X-ray photoelectron spectroscopy. The effectiveness of combining the oxygen plasma treatment and silane coupling agent (SCA) derivatization in adhesion promotion for an epoxy bonded to a silicon surface was evaluated in this research. SCAs with different amine functionalities were studied. The oxygen plasma treatment time was varied systematically to achieve a different extent of oxidation on the Si wafer. The surface chemistry/composition of various silane derivatized Si surfaces was investigated. The studies revealed that SCA interaction with the Si surface was enhanced by the oxygen plasma pre-treatment of the Si substrates. XPS surface analysis results showed that the SCA/SiO2 ratio did not correlate strongly with the increase in oxygen plasma pretreatment time. However, for Si surfaces treated for longer oxygen plasma pretreatment times, more silanol groups may be available to interact with the hydrolyzed silanol groups on silane, resulting in a stronger SCA-Si attachment. Three different tests were employed to determine adhesion and durability of the model epoxy/SCA/SiO2/Si bonded specimens. The immersion test qualitatively evaluates the bond durability for various systems exposed to different chemical and thermal conditions. Second, a novel probe test was used to quantitatively determine adhesion under critical debonding conditions for bonded specimens with different SCA preparations. A general trend of bond durability varied in the manner SCA-2 > SCA-3 > SCA-1 > no silane. Bond durability also increased for samples: model epoxy/SCA modified/O2 plasma treated/Si as the oxygen plasma pre-treatment time increased. Third, bond durability was studied using the wedge DCB (double cantilever beam) test under subcritical debonding conditions with environment-assisted crack growth as a function of applied strain energy release rate. Higher crack velocity and the absence of a Gthreshold value were noted in tests at 70 oC. The Gthreshold value increased as the strength of the interface increased and as the chemical aggressiveness of the environment decreased. For tests involving 25 oC -70 oC thermal cycling, only limited crack growth was found. / Ph. D.

probe test

silane coupling agent

durability

failure analysis

silicon surface modification

plasma treatment

adhesion

epoxy

X-ray photoelectron spectroscopy

Fonctionnalisation et caractérisation multi-échelle de films minces de chitosane : vers une utilisation en ingénierie tissulaire / Functionalization and multi-scale characterisation of chitosan films for tissue engineering application

Zhang, Hongyuan

16 December 2014

Ce travail porte sur la fonctionnalisation en volume et/ou en surface et la caractérisation multi-échelle de films minces de chitosane utilisés en ingénierie tissulaire. L’ajout des nanoliposomes à base de lécithine naturelle (végétale ou marine) et un traitement plasma sont employés pour réaliser ces deux fonctionnalisations. De nombreuses analyses des caractéristiques physico-chimiques et « structurales » de films minces ont montré que lorsqu’on ajoute 10 % de nanoliposomes dans les films de chitosane, l’hydrophobicité de la surface s’améliore de 18 à 36 %, ce fait est attribué à la présence de composants polaires. La cristallinité est légèrement augmentée ; à 37 °C, le module d’Young diminue de 6 GPa environ jusqu’à près de 4 GPa ; aucune nouvelle liaison ne se crée entre le chitosane et les nanoliposomes ; une diminution de degré de déacétylation est observée, qui pourrait être associée à la conformation des nanoliposomes ajoutés en volume aux films de chitosane. Le traitement plasma a réussi à modifier la structure de surface du chitosane seul et du chitosane mélangé aux nanoliposomes par greffe de groupements actifs (groupes amine, C-O, COOH, -OH). En revanche, dans notre cas, les liaisons hydrogène entre les groupes polaires créés par le traitement plasma peuvent être éliminées partiellement après un temps donné, ce qui limite l’application du traitement. Ensuite, des études préliminaires sur la biocompatibilité in vitro et la biodégradabilité in vitro sont réalisées pour les films de chitosane et du chitosane mélangé aux nanoliposomes. Les cellules souches mésenchymateuses sont utilisées pour l’étude de la première, et une solution de PBS contenant 10 mg/L de lysozyme pour la seconde. Les propriétés physico-chimiques des films de chitosane mélangé aux nanoliposomes marines, leur faible cytotoxicité aux cellules et leur stabilité dans la solution de PBS contenant du lysozyme leur permettent d’être utilisés comme matrice de support dans le domaine de la médecine régénérative / This work focused on functionalized chitosan thin films in the bulk and/or on the surface by nanoliposomes based on natural lecithin (plant and marine) and plasma treatment. Various techniques were used for physicochemical properties analysis of functionalized thin films. The results showed that by adding the nanoliposomes into the chitosan scaffold, the surface wettability of thin films increased from 18 % to 36 %. The crystallinity degree was slightly improved in blend thin films. Any new bond was determined by fourier transform infrared spectroscopy (FTIR), which confirmed that there is no chemical interaction between the nanoliposomes and chitosan. The Young’s modulus of blend thin films deceased from 6 GPa to 5 GPa. The morphological, nanomechanical properties and adhesion force of each scaffold system determined by Scanning Probe Microscopy (HarmoniXTM mode) showed that the fish nanoliposomes/chitosan thin film had the most similar properties compared to the pure chitosan thin film. The surface of chitosane films and nanoliposomes/chitosane blend films were modified by the plasma treatment. Functional groups (amine groups, C-O, COOH, -OH) are grafted onto the surface enhancing thus the surface energy of the films. But the hydrogen bonds between the polar groups introduced by the treatment can be destroyed after a given time; the author proposed that the functionalization in the bulk by adding of nanoliposomes provided more stable and greater possibility of new materials producing than the functionalization at the surface by plasma treatment for potential tissue engineering application. Then, in vitro biocompatibility preliminary study was carried using human mesenchymal stem cells (hMSCs); and in vitro biodegradability study was tested in the phosphate buffered saline (PBS) mixed with 10 mg/L lysozyme. The films of chitosan functionalized by salmon nanoliposomes showed more interesting as matrix extracellular for regenerative medicine applications because of their physico-chemical properties, low cytotoxicity and the stability inside the PBS and lysozyme solutions.

Chitosane

Nanoliposomes

Fonctionnalisation en volume

Traitement plasma

Biocompatibilité in vitro

Biodégradabilité in vitro

Chitosan

Nanoliposomes

Functionalization in volume

Plasma treatment

In vitro biocompatibility

In vitro biodegradability

620.117

660.6

Compréhension des mécanismes de modification de surface d’élastomères non réticulés consécutifs à une exposition plasma et ses conséquences sur le comportement adhésif / Understanding mechanisms of surface modification of unvulcanized elastomers after plasma treatment and aftermath on adhesive behaviour

Henry, Alicia

31 August 2015

Les traitements plasma sont devenus des moyens incontournables et puissants pour modifier les propriétés de surface de nombreux matériaux sans intervenir sur les propriétés massiques et ceci en étant respectueux de l’environnement. Si ces traitements ont été appliqués à de nombreuses reprises aux élastomères réticulés pour améliorer leurs propriétés d’adhérence, ils n’ont quasiment jamais été appliqués à des élastomères non réticulés. Les expositions plasma ont été réalisées à basse pression, en décharge radiofréquence dans un environnement d’air. Pour limiter la complexité de l’étude et pour obtenir une meilleure compréhension des mécanismes d’interaction plasma-surface, un SBR et un polybutadiène (BR) non chargés et non réticulés ont été utilisé comme élastomères modèles. Le rôle d’un d’antioxydant (6PPD) classiquement utilisé a également été étudié. L’influence de la configuration du réacteur plasma sur les modifications surface a été suivie par mouillabilité et spectroscopie XPS. La cartographie des espèces plasmagènes a été obtenue par spectroscopie d’émission optique.L’augmentation du caractère hydrophile des surfaces avec l’énergie du plasma jusqu’à un seuil énergétique a pu être mise en évidence. Au-delà les phénomènes d’ablation et de réticulation de surface deviennent prépondérants. Les modifications de surface et leur cinétique de réorganisation de surface des chaînes polymère dépendent essentiellement de la température, l’environnement est un paramètre secondaire. L’influence de ces modifications physico-chimiques de surface induite sur les propriétés de tack est clairement mise en évidence. L’augmentation du caractère hydrophile conduit à une augmentation importante des performances adhésives instantanées (temps courts de contact 100s) au contact du verre. Par contre, la réticulation superficielle consécutive à des expositions plasma trop énergétiques diminue de façon drastique l’autohésion, ie le contact entre deux surfaces élastomères traitées. Le rôle de l’antioxydant sur la recombinaison des radicaux macromoléculaires formés lors du traitement a été montré. Le succès de la mise en œuvre d’un traitement de surface par plasma repose sur le contrôle du seuil énergétique à ne pas dépasser de sorte à minimiser les phénomènes de réticulation superficielle. / Plasma treatment has become a powerful candidate to modify surface properties without any change in bulk properties. It combines high chemical reactivity with low operational costs, in environmentally friendly processes. Plasma treatment has been intensively applied for surface modification of vulcanized rubbers. Almost no studies have been dedicated to plasma treatment of unvulcanized rubbers. The role of each additive during plasma exposure is poorly understood. It is also admitted that surface crosslinking occurs easily on rubber surfaces exposed to plasmas. This impacts the adhesive properties of the rubbers because it mimics chain interdiffusion. In this context, determining the key plasma parameters that have a significant effect on the surface properties is a prerequisite for further process control. To limit the complexity of the study, we concentrated our efforts on unvulcanized filler-free styrene butadiene rubber (SBR) and polybutadiene rubber (BR) which has been used for the first time as rubber models. The effect of three main parameters that directly impact the amount of energy and the nature of the excited species in the plasma phase (i.e. the RF source power, the exposure time and the distance between the rubber samples and the plasma) was analyzed. Optical Emission Spectroscopy was used to characterize the plasma phase. Surface modifications were investigated by wettability measurements and X-Ray Photoelectron Spectroscopy. Surface aging was investigated under ambiant and inert atmosphere at different temperatures and finally tack properties were measured and connected to surface properties determined with optical emission spectroscopy.

Traitement plasma air

Elastomère

Adhésion

Additifs

Polybutadiène

Antioxydants

Diagnostic plasma

Air plasma treatment

Rubber

Adhesion

Additives

Polybutadiene

Antioxidants

Plasma diagnostic

540

Optimisation de la structure textile des prothèses vasculaires pour un développement en monocouche des cellules endotheliales / Vascular textile prostheses optimization for an endothelial cells monolayer devlopment

François, Sébastien

07 December 2009

Les prothèses vasculaires textiles en polyéthylène téréphtalate (PET) présentent souvent des occlusions après implantation pour les petits diamètres (6-8mm) car la surface des prothèses est peu hémocompatible. Or, l'hémocompatibilité des prothèses serait largement améliorée si ces dernières se recouvraient d'une couche de cellules endothéliales qui tapissent naturellement les vaisseaux sanguins. Ce projet vise à mettre en évidence que les textiles bruts ne sont pas un support viable pour le développement de ces cellules endothéliales, puis propose de remplacer les matrices protéiniques par un recouvrement synthétique. Pour ce faire, de l'acide poly-L-lactique (PLA) solubilisé a été filé sous forme de nanofibres déposées sur la surface luminale de la prothèse. L'étirage par jet d'air a été caractérisé selon un modèle plan, puis adapté à la fon11e tubulaire des prothèses. Les nanofibres ont été évaluées sur le plan de la cytocompatibilité, de l'adhérence et de la prolifération avec un modèle de cellules endothéliales animales. Ce travail vise aussi à optimiser l'adhérence de ces fibres sur le PET par l'emploi d'une technique de modification de surface par plasma. Les résultats montrent qu'il est possible de produire des nanofibres de PLA et de contrôler leur diamètre, et de sceller la paroi de la prothèse textile. Enfin, les cellules endothéliales prolifèrent en monocouche sur des prothèses recouve1tes de nanofibres. Il est possible d'optimiser l'adhérence des nanofibres sur le PET avec un traitement par plasma. En conclusion nous avons proposé une alternative à l'enduction traditionnelle des prothèses permettant la prolifération en monocouche des cellules endothéliales. / Textile vascular prostheses show poor patency rate for smaller diameter grafts (6-8mm). Mainly due to thrombosis or hyperplasia, graft failures can be explained by meagre hemocompatibility. Lack of neoendothelialization of the inner wall of the graft can be one reason explaining this poor hemocompatibility, This project aimed to prove that bare textiles are not a good support to stand endothelial cells' proliferation. Poly(L-latic) acid was therefore chosen to replace protein coating by being formed as a nanofibres mesh on the PET textile prostheses luminal surface. Air jet spinning process was first evaluated in a basic planar model to determined optimal parameters for nanofibres production. Endothelial cells compatibility, adhesion and proliferation were tested. Then air jet spinning was dedicated to tubular shape of textile vascular prostheses. Nanofibres mesh were analysed for chemical and physical properties, and covered graft were tested for water permeability. Lastly, atmospheric pressure plasma treatment was performed to optimize PLLA nanofibres adhesion on PET. Results showed that nanofibre diameters were controlled by polymer concentration. Nanofibre cristallinities depend of spinning parameters. Air jet spinning allows quick covering of textile surfaces with a dense net of nanofibre scelling the inner wall of the prosthesis, even in tubular samples. Moreover, endothelial ceIls show monolayer proliferation on these nanofibres. Finally, Polylactic acid adhesion on PET was optimized with atmospheric pressure plasma. In conclusion, we bring a new solution to cover inner wall of prostheses, allowing a monolayer proliferation of endothelial cells.

Prothèse vasculaire

Endothélialisation

Structure textile

Pet

Plla

Nanofibres

Traitement plasma

Filage par jet d'air

Vascular Prothese

Endothelialization

Textile structure

Pet

Plla

Nanofibers

Plasma treatment

Air-jet spinning

Funktionalisierung von Silikonoberflächen

Roth, Jan

10 February 2009

Poly(dimethylsiloxan) (PDMS) ist ein wichtiges Polymer, das zunehmend in der Mikroelektronik aufgrund seiner hervorragenden Elastizität und thermischen Stabilität Verwendung findet. Ein limitierender Faktor für den Einsatz von PDMS ist aufgrund des Fehlens von reaktiven Gruppen und der niedrigen freien Oberflächenenergie seine geringe Adhäsion zu anderen Materialien. Zur Erhöhung der Adhäsion ist deshalb die Einführung von polaren, funktionellen Gruppen notwendig. Hier lag die Motivation der vorliegenden Arbeit, die sich eine gezielte Funktionalisierung von PDMS-Oberflächen als Aufgabe gesetzt hatte. Im ersten Teil der Arbeit wurde eine Verbesserung der Adhäsion zu einem fotostrukturierbaren Epoxidharz mittels der Sauerstoff- und Ammoniakplasmabehandlung angestrebt. In beiden Fällen führte die Plasmabehandlung zu der Einführung von unterschiedlichsten funktionellen Gruppen auf die Oberfläche und zu einer Verbesserung des Benetzungsverhaltens gegenüber Wasser. Zudem wurden Haftfestigkeiten erzielt, die um ein Vielfaches höher waren als jene zwischen Epoxidharz und einer unbehandelten PDMS-Oberfläche. Jedoch waren die hydrophilen Eigenschaften nach der Plasmabehandlung während der Lagerung an Luft zeitlich begrenzt, die PDMS-Oberfläche kehrt innerhalb kurzer Zeit in den einst hydrophoben Ausgangszustand zurück. Der Alterungsvorgang wird als „Hydrophobic Recovery“ bezeichnet und ist bei PDMS-Oberflächen, die höheren Plasmaleistungen und Behandlungszeiten ausgesetzt wurden, besonders auffällig. Die Vermeidung dieser Problematik war der Ausgangspunkt für den zweiten Teil der Arbeit. Auf der Grundlage der über die Plasmabehandlungen erzeugten funktionellen Gruppen wurden neue Konzepte für eine kovalente Anbindung von verschiedenen funktionellen Homo- und Copolymeren über die „Grafting to“-Technik entwickelt. Neben der Erhöhung der Adhäsion zu dem Epoxidharz war es möglich, das Benetzungsverhalten gegenüber Wasser durch die Unterbindung der „Hydrophobic Recovery“ zu stabilisieren. Des Weiteren gelang es, durch die Wahl der funktionellen Polymere, die PDMS-Oberfläche gezielt mit gewünschten Eigenschaften auszustatten. Somit ist der Einsatz der polymermodifizierten Oberflächen, außer in der Mikroelektronik, auch auf andere Anwendungen, wie der Biomedizin, der Mikrofluidik oder der Softlithografie übertragbar, in denen eine beständige, definierte Oberflächenfunktionalisierung ein wichtiges Kriterium darstellt.

Poly(dimethylsiloxan)

Niederdruckplasmabehandlung

Adhäsion

freie radikalische Polymerisation

Grafting

poly(dimethyl siloxane)

low pressure plasma treatment

adhesion

free radical polymerization

grafting

ddc:540

rvk:VK 8007

Synthesis, Characterization and Applications of Metal Oxide Nanostructures

Hussain, Mushtaque

January 2014

The main objective of nanotechnology is to build self-powered nanosystems that are ultrasmall in size, exhibit super sensitivity, extraordinary multi functionality, and extremely low power consumption. As we all know that 21st century has brought two most important challenges for us. One is energy shortage and the other is global warming. Now to overcome these challenges, it is highly desirable to develop nanotechnology that harvests energy from the environment to fabricate self-power and low-carbon nanodevices. Therefore a self-power nanosystem that harvests its operating energy from the environment is an attractive proposition. This is also feasible for nanodevices owing to their extremely low power consumption. One advantageous approach towards harvesting energy from the environment is the utilization of semiconducting piezoelectric materials, which facilitate the conversion of mechanical energy into electrical energy. Among many piezoelectric materials ZnO has the rare attribute of possessing both piezoelectric and semiconducting properties. But most applications of ZnO utilize either the semiconducting or piezoelectric property, and now it’s time to fully employ the coupled semiconducting-piezoelectric properties to form  the basis for electromechanically coupled nanodevices. Since wurtzite zinc oxide (ZnO) is structurally noncentral symmetric and has the highest piezoelectric tensor among tetrahedrally bonded semiconductors, therefore it becomes a promising candidate for energy harvesting applications. ZnO is relatively biosafe and biocompatible as well, so it can be used at large scale without any harm to the living environment. The synthesis of another transition metal oxide known as Co3O4 is also important due to its potential usage in the material science, physics and chemistry fields. Co3O4 has been studied extensively due to low cost, low toxicity, the most naturally abundant, high surface area, good redox, easily tunable surface and structural properties. These significant properties enable Co3O4 fruitful for developing variety of nanodevices. Co3O4 nanostructures have been focused considerably in the past decade due to their high electro-chemical performance, which is essential for developing highly sensitive sensor devices. I started my work with the synthesis of ZnO nanostructures with a focus to improve the amount of harvested energy by utilizing oxygen plasma treatment. Then I grow ZnO nanorods on different flexible substrates, in order to observe the effect of substrate on the amount of harvested energy. After that I worked on understanding the mechanism and causes of variation in the resulting output potential generated from ZnO nanorods. My next target belongs to an innovative approach in which AFM tip decorated with ZnO nanorods was utilized to improve the output energy. Then I investigated Co3O4 nanostructures though the effect of anions and utilized one of the nanostructure to develop a fast and reliable pH sensor. Finally to take the advantage of higher degree of redox chemistry of NiCo0O4 compared to the single phase of nickel oxide and cobalt oxide, a sensitive glucose sensor is developed by immobilizing glucose oxidase. However, there were problems with the mechanical robustness, lifetime, output stability and environmental adaptability of such devices, therefore more work is going on to find out new ways and means in order to improve the performance of fabricated nanogenerators and sensors.

Aqueous chemical growth method

ZnO nanorods

Oxygen plasma treatment

Piezoelectric and mechanical properties

Atomic force microscope

Nanoindentation

Co3O4 nanostructures

Anions effect

pH sensor

NiCo2O4 nanostructures

Glucose sensor

Estudo da ades?o de pinos endod?nticos modificados superficialmente por plasma de oxig?nio / Pilot study of the adhesion of posts endodontics modified superficially by oxygen in plasma treatment

Guerra, T?cio Dantas de Brito

13 November 2007

Made available in DSpace on 2014-12-17T14:06:48Z (GMT). No. of bitstreams: 1 TacioDBG.pdf: 1757176 bytes, checksum: 3cabe1cee719475706ab99a62bb862f6 (MD5) Previous issue date: 2007-11-13 / Coordena??o de Aperfei?oamento de Pessoal de N?vel Superior / The work presents the effect of plasma treatment when applied in fibers or carbon/glass posts in the adhesion fiber/resin and posts/cement. This has for objective the modification of the surface of the fibers, as well as the wettability of the posts, seeking the improvement of the adhesion and of the connection fiber/resin in the processing of polymeric composites reinforced with the same ones. 120 posts (Reforpost) were used and 30 meters of fibers of carbon and of glass (Fibrex), of the company Angelus. The samples were divided in three groups of 40 specimens: GROUP I - 20 posts of glass fiber and 20 of carbon without treatment to it shapes, GROUP II -20 posts of glass fiber and 20 of carbon treated to it shapes in the surface and GROUP III - 20 posts of glass fiber and 20 of carbon make with fibers in natura after plasma treatment. The plasma treatment was accomplished with oxygen and with temperature in the camera fixed at 200?C, for one hour of exhibition. The posts and the fibers were characterized before and after the treatment. The wettability was measure by pendent drop method, and interface fiber/resin and posts/cement were observed by optical and electronic microscopy. It was observed that both wettability and texture were increased with plasma treatment / O presente trabalho aborda o tratamento superficial a plasma de pinos e fibras de carbono e de vidro, para uso odontol?gico. Este tem por objetivo a modifica??o da superf?cie das fibras, bem como a superf?cie dos pinos, visando a melhoria da ades?o fibra/resina e pino/cimento. Foram utilizados 120 pinos (Reforpost) e 30 metros de fibras de carbono e de vidro (Fibrex), da empresa Angelus. As amostras foram divididas em tr?s grupos de 40 esp?cimes: GRUPO I - 20 pinos de fibra de vidro e 20 de fibra de carbono sem tratamento em plasma, GRUPO II -20 pinos de fibra de vidro e 20 de carbono tratados a plasma na superf?cie e GRUPO III- 20 pinos de fibra de vidro e 20 de carbono confeccionados a partir do tratamento em plasma da fibra in natura . O tratamento em plasma foi realizado com atmosfera de oxig?nio durante 1 hora. Tanto as fibras como os pinos foram colocados a uma dist?ncia de 7cm, de modo a evitar o aquecimento dos mesmos. A temperatura do catodo foi de 200?C. Os pinos e as fibras foram caracterizados antes e ap?s o tratamento, atrav?s de metalografia, microscopia ?tica e eletr?nica de varredura. Em seguida, foram realizados ensaios de capilaridade das fibras, tor??o e molhabilidade nos pinos. Os resultados mostram que o tratamento empregado modifica a superf?cie das fibras, aumenta a molhabilidade dos pinos, modifica a textura superficial de ambos quando em compara??o com as amostras sem tratamento, como tamb?m demonstra um aumento da ades?o das interfaces fibra/matriz e pino/cimento resinoso

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omp?sitos

Pinos de fibra

Ades?o

Tratamento a plasma

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mposite

Fiber posts

Adhesion

Plasma treatment