Preparation Of Functional Surfaces Using Zeolite Nanocrystals For Biosensor And Biomedical Applications

Kirdeciler, Salih Kaan

01 July 2012

Zeolites are crystalline aluminosilicates which have highly ordered pore structures and high surface area. Also the tailorable surface properties, high ion-exchange capability, high chemical, thermal, and mechanical strength make these particles an important candidate for various application such as sensors, catalysis, dielectric materials, separation, and membrane technologies. Although zeolites have these unique properties, applications where zeolites are integrated into devices according to their application areas, are limited due to the powder form of the material. The purpose of the current study was to investigate the effect of zeolite nanoparticles on conductometric biosensor performance and cell viability measurements. Firstly, zeolite attachment on silicon surfaces was investigated by attaching silicalite and zeolite A nanoparticles onto the silicon substrates by direct attachment methodology in a closely packed monolayer form with perfect orientation and full coverage without using any chemical linker. Furthermore, the ability to pattern these zeolite crystals on silicon substrates with electron beam lithography and photolithography techniques was investigated. With the combination of electron beam lithography and direct attachment methodology, zeolite patterns were produced with feature sizes as small as a single silicalite nanoparticle thick line, that is approximately 500 nm. This approach has the ability of patterning very small features on silicon substrate, but the drawback is the long patterning time and lack of electron beam stability during long pattern formation process. Accordingly, it is almost impossible to form large patterns with electron beam lithography systems. Afterwards, to have full control on surfaces with differentiated areas on solid substrates, patterns of one type of zeolite crystals was formed on the monolayer of another type of zeolite layer with electron beam lithography for the first time. The same closed packed and highly oriented silicalite patterns were successfully formed on zeolite A monolayers and vice versa. Then photolithography technique was combined with direct attachment methodology to overcome the problem of the lack of total patterned area. With this technique, it was possible to pattern the whole silicon wafer in a couple of seconds, however the feature size of the zeolite patterns was limited with the infrastructures of the mask fabricated for photolithography studies. In this particular study, zeolite lines patterns with a minimum of 5 &micro / m thickness were prepared and the total patterned area was kept constant at 1 cm2. Similar to what was obtained by electron beam lithography study, zeolite A patterns were formed on silicalite monolayers with the minimum feature size of 5 &micro / m and vice versa. In the second part of the study, zeolite films were prepared on the transducers of conductometric biosensors using dip coating technique and named as Zeolite Coated Transducers (ZCT). Electrodes prepared using a mixture of zeolite and enzyme solution and then subjected to casting using glutaraldehyde were called Zeolite Membrane Transducers (ZMT). The operational and storage stabilities were determined to be in an acceptable range using ZCTs for conductometric urea biosensors. It was observed that using electrodes fabricated by the ZCT technique enhanced the biosensor signals up to two times and showed a rapid response after the addition of urea to the medium when it was compared with Standard Membrane Transducers (SMT). This enhancement can be explained by the lack of GA layer on top of the film, which acts as a diffusion barrier and inhibits the activity of the enzyme. On the second part of this conductometric biosensor study, effect of zeolite modification with methyl viologen (MV) and silver nanoparticles (Ag+ and Ag0), as well as the effect of changing Si/Al ratio was investigated with three different zeolite Beta particles which have Si/Al ratios of 40, 50, and 60. There were no significant effect of MV modification on ZMTs and there was no response observed with Ag+ and Ag0 modified zeolites. However, it was observed that conductometric responses increased with increasing Si/Al ratio for ZMTs. This behavior can be due to an increased hydrophobicity and/or the increasing acidic strength with the increasing Si/Al ratio within the zeolite crystals. Also ZCTs showed higher responses with respect to both SMTs and ZMTs. When compared with SMTs and ZMTs, ZCTs had higher reproducibility due to the controlled thickness of zeolite thin film by dip coating, and the controlled amount of enzyme adsorbed on this film. In the third part of the study, effect of zeolites on cell proliferation with MG63 osteoblast cells and NIH3T3 fibroblast cells were investigated. For that purpose, zeolite A, silicalite, and calcined forms of these zeolites were patterned with photolithography technique onto silicon wafers. Three different patterns prepared for this particular study, which has 0.125cm2, 0.08825cm2, and 0.04167cm2 zeolite patterned areas on 1 cm2 samples. In that way, not only the zeolite type and effect of calcination of zeolites, but also the effect of zeolite amount on MG63 osteoblast cells and NIH3T3 fibroblast cells were investigated. Silicalite coated samples were observed to have higher amount of cells than zeolite A coated samples after 24, 48, and 72 hours of incubation. This may be referred to the hydrophilic/hydrophobic properties, surface charge, and/or particle size of zeolites. Also it is observed that higher zeolite amount on samples resulted in an increase in the number of cells attached to the samples. There was also a significant increase in the number of cells upon using calcined silicalite samples. Accordingly, it can be hypothesized that zeolite pores result in an enhancement of protein adsorption and proliferation, even if this only occurs at the pore openings. On the other hand, there was no positive effect of calcining zeolite A. This result was expected since there is no structure directing agent used in synthesis procedure of zeolite A, which again supports the fact that pores might have some role in cell attachment.

QD Chemistry 1-999

Transporte eletrônico em biofilmes nanoestruturados para biossensores a base de enzimas / Electronic transport in nanostructures films for biosensors based in enzymes

Valencia, Germán Ayala

21 March 2013

Os biossensores são dispositivos empregados para a detecção de um analito específico, podendo assim ser no controle de qualidade nos alimentos para determinar a presença de micro-organismos, toxinas ou metabólitos. O presente estudo objetiva desenvolver um biossensor condutométrico, baseado na imobilização de peroxidasse em membranas de quitosana e quitosana com nanopartículas de ouro (AuNP) para a detecção de peroxido de hidrogênio. O trabalho foi dividido em três etapas. Na primeira etapa foi estudada a obtenção de AuNP empregando agentes redutores biológicos, sendo avaliados três monossacarídeos (glicose, frutose e galactose), três dissacarídeos (sacarose, maltose e lactose), dois biopolímeros (amido e quitosana), assim como os extratos obtidos a partir das folhas de hortelã (Mentha piperita) e cascas de furtas de abacaxi (Ananas comosus), banana (Musa sp. ), maracujá (Passiflora edulis), tangerina (Citrus reticulata). A quitosana mostrou-se como o melhor agente redutor na síntese das AuNP, as quais foram empregadas na segunda etapa para a produção de membranas. Três tipos de membranas foram processadas, membranas de quitosana sem AuNP e membranas de quitosana com AuNP com concentrações de 8 e 11mM., as quais foram caraterizadas morfológica e eletricamente. Finalmente foi avaliada a imobilização da peroxidasse usando quatro tratamentos diferentes, sendo a dispersão da peroxidasse nas soluções filmogênicas precursoras das membranas a mais eficiente. A resposta elétrica destas membranas é dependente da concentração de AuNP e da presença de enzimas, e também foi alterada quando as mesmas foram expostas a soluções de tampão fosfato com diferentes concentrações de peroxido de hidrogênio. Isto constitui o principio de operação dos biossensores condutométricos desenvolvidos neste trabalho. / Biosensors are devices used for detecting a specific analyte, and thus can be used in quality control of food for determining the presence of micro-organisms, toxins or metabolites. The present study aims to develop a conductometric biosensor based on the immobilization of peroxidase in membranes of chitosan and chitosan with gold nanoparticles (AuNP) for the detection of hydrogen peroxide. The work was divided into three stages. In the first stage, methods for obtaining AuNP employing biological reducing agents were studied, evaluating three monosaccharides (glucose, fructose and galactose), three disaccharides (sucrose, maltose and lactose), two biopolymers (starch and chitosan), as well as the extracts obtained from the leaves of mint (Mentha piperita) and husks dost thou pineapple (Ananas comosus), banana (Musa sp), passion fruit (Passiflora edulis), mandarin (Citrus reticulata). Chitosan exhibited the best behavior as reducing agent for the synthesis of AuNP, which were employed in the second step for the production of membranes. Three types of membranes were processed, chitosan membranes without AuNP and chitosan membranes with AuNP with concentrations of 8 and 11mM, which were morphologically and electrically characterized. Finally the peroxidase immobilization was evaluated using four different procedures, being the dispersion of the peroxidase in filmogenic solutions precursor of membranes the more efficient. The electrical response of these membranes, depends on the AuNP concentration and the presence of enzymes, and was also altered when they were exposed to hydrogen peroxide containing phosphate buffer solutions. This constitutes the principle of operation of the conductometric biosensor developed in this work.

Biossensor condutométrico

Chitosan

Conductometric biosensor

Electronic transport

Food industry

Gold nanoparticles

Hydrogen peroxidase

Indústria de alimentos

Nanopartículas de ouro

Peroxido de hidrogênio

Quitosana

Transporte eletrônico

Transporte eletrônico em biofilmes nanoestruturados para biossensores a base de enzimas / Electronic transport in nanostructures films for biosensors based in enzymes

Germán Ayala Valencia

21 March 2013

Os biossensores são dispositivos empregados para a detecção de um analito específico, podendo assim ser no controle de qualidade nos alimentos para determinar a presença de micro-organismos, toxinas ou metabólitos. O presente estudo objetiva desenvolver um biossensor condutométrico, baseado na imobilização de peroxidasse em membranas de quitosana e quitosana com nanopartículas de ouro (AuNP) para a detecção de peroxido de hidrogênio. O trabalho foi dividido em três etapas. Na primeira etapa foi estudada a obtenção de AuNP empregando agentes redutores biológicos, sendo avaliados três monossacarídeos (glicose, frutose e galactose), três dissacarídeos (sacarose, maltose e lactose), dois biopolímeros (amido e quitosana), assim como os extratos obtidos a partir das folhas de hortelã (Mentha piperita) e cascas de furtas de abacaxi (Ananas comosus), banana (Musa sp. ), maracujá (Passiflora edulis), tangerina (Citrus reticulata). A quitosana mostrou-se como o melhor agente redutor na síntese das AuNP, as quais foram empregadas na segunda etapa para a produção de membranas. Três tipos de membranas foram processadas, membranas de quitosana sem AuNP e membranas de quitosana com AuNP com concentrações de 8 e 11mM., as quais foram caraterizadas morfológica e eletricamente. Finalmente foi avaliada a imobilização da peroxidasse usando quatro tratamentos diferentes, sendo a dispersão da peroxidasse nas soluções filmogênicas precursoras das membranas a mais eficiente. A resposta elétrica destas membranas é dependente da concentração de AuNP e da presença de enzimas, e também foi alterada quando as mesmas foram expostas a soluções de tampão fosfato com diferentes concentrações de peroxido de hidrogênio. Isto constitui o principio de operação dos biossensores condutométricos desenvolvidos neste trabalho. / Biosensors are devices used for detecting a specific analyte, and thus can be used in quality control of food for determining the presence of micro-organisms, toxins or metabolites. The present study aims to develop a conductometric biosensor based on the immobilization of peroxidase in membranes of chitosan and chitosan with gold nanoparticles (AuNP) for the detection of hydrogen peroxide. The work was divided into three stages. In the first stage, methods for obtaining AuNP employing biological reducing agents were studied, evaluating three monosaccharides (glucose, fructose and galactose), three disaccharides (sucrose, maltose and lactose), two biopolymers (starch and chitosan), as well as the extracts obtained from the leaves of mint (Mentha piperita) and husks dost thou pineapple (Ananas comosus), banana (Musa sp), passion fruit (Passiflora edulis), mandarin (Citrus reticulata). Chitosan exhibited the best behavior as reducing agent for the synthesis of AuNP, which were employed in the second step for the production of membranes. Three types of membranes were processed, chitosan membranes without AuNP and chitosan membranes with AuNP with concentrations of 8 and 11mM, which were morphologically and electrically characterized. Finally the peroxidase immobilization was evaluated using four different procedures, being the dispersion of the peroxidase in filmogenic solutions precursor of membranes the more efficient. The electrical response of these membranes, depends on the AuNP concentration and the presence of enzymes, and was also altered when they were exposed to hydrogen peroxide containing phosphate buffer solutions. This constitutes the principle of operation of the conductometric biosensor developed in this work.

Biossensor condutométrico

Indústria de alimentos

Nanopartículas de ouro

Peroxido de hidrogênio

Quitosana

Transporte eletrônico

Chitosan

Conductometric biosensor

Electronic transport

Food industry

Gold nanoparticles

Hydrogen peroxidase

Encapsulation de la myoglobine dans des microsphères de poly(epsilon-caprolactone) : étude des paramètres de formulation et de procédé sur les propriétés des particules et sur l’intégrité protéique / Myoglobin encapsulation in PCL-microspheres : study of formulation and process parameters on particle properties and protein integrity

Ruffin, Émilie

23 April 2010

L'encapsulation de protéines pose de nombreuses difficultés liées à leurs propriétés physicochimiques, leur sensibilité aux conditions environnementales et opératoires. La structure 3D spécifique de chaque protéine étant directement liée à son activité biologique, un contrôle de l'intégrité protéique est indispensable pour assurer l'efficacité et la sécurité des systèmes formulés. Dans cet optique, l'encapsulation par émulsion multiple a été appliquée à une protéine modèle : la myoglobine (Mb). Le but de cette thèse a été l'étude du procédé d'encapsulation à travers 3 objectifs. Le premier fut d'étudier l'influence de paramètres de formulation sur les propriétés des particules obtenues et sur la conformation de la Mb. Les mesures en spectrométrie UV/Vis. et le calcul des principaux rapports d'absorbance ont constitué une méthode de contrôle fiable et rapide. Le second fut de valider la pertinence et de montrer les limites de cette méthode en la comparant à une seconde méthode utilisant des mesures conductimétriques. Enfin, l'étape de solidification des particules par élimination du solvant ainsi que le changement de solvant ont été étudiés.. Des microsphères creuses de 15μm avec un rendement d'encapsulation de 36% ont pu être obtenues tout en maintenant la conformation native de la Mb. L'emploi de polymère de masse moléculaire élevée et un taux d'élimination de solvant trop rapide sont 2 paramètres altérants significativement la protéine. Ces travaux ouvrent la voie au développement de transporteurs d'O2 utilisables par exemple dans le cas de pathologies musculaires / Protein encapsulation results in several problems related to their physicochemical properties, their sensitivity to environmental conditions and operating procedures. The specific 3D structure being directly linked to their biological activity, monitoring of protein integrity is crucial to ensure the efficacy and security of formulations. In this context, the multiple emulsion method was applied to a model protein: myoglobin (Mb). The aim of this thesis was to study the encapsulation process through 3 objectives. The first was to study the influence of formulation parameters on the particle properties and the conformation of Mb. Measurements by UV/Vis. spectrometry and calculation of key absorbance ratios established a reliable and rapid method for protein monitoring. The second was to validate the pertinence and show the limits of this method by comparing it to a second one using conductimetry measurements. Finally, the particle solidification by solvent removal and the solvent exchange were studied. The process maintains the Mb native conformation in Hollow microspheres of 15μm in diameter and an encapsulation efficiency of 36% were obtained, while keeping intact the Mb native conformation. The use of high molecular weight polymer and a fast solvent removal rate are 2 parameters inducing significant protein alteration. This work paves the way for the development of O2 carriers for muscular diseases for example

Microsphères

Myoglobine (Mb)

Émulsion multiple

Spectrométrie UV/Vis

Intégrité protéique

Biocapteur conductimétrique

Microspheres

Myoglobin (Mb)

Multiple emulsion

UV/Vis spectrometry

Protein integrity

Conductometric biosensor

660.071