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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.
401

Impedimetric and electrode kinetic dynamics of DNA aptamer nanobiosensors for estrogeneous endocrine disruptors

Olowu, Rasaq Adewale January 2011 (has links)
Philosophiae Doctor - PhD / In this work, DNA aptamer biosensor systems were developed for the detection of l7p-estradiol - an estrogeneous endocrine disrupting chemical (EDC). Endocrine disrupting chemicals are group of compounds that impact negatively on the endocrine system of humans and wildlife. High concentrations of l7p-estradiol in water or food chain disrupts the physiology of the endocrine system of various animal species, leading to feminisation in fish and stimulates the proliferation of cancer cells in humans. Aptasensor systems for the determination of l7pestradiol were prepared with three immobilization platforms: (i) poly(3,4- ethylenedioxythiophene) {PEDOT} doped with gold nanoparticles (AuNPs) to form PEDOTIAuNPs polymeric nanocomposite, (ii) generation 1 poly(propylene thiophenoimine)-copoly( 3 ,4-ethy lenedioxythiophene) dendritic star copolymer (G 1PPT -co-PEDOT), and (iii) generation 2 poly (propylene thiophenoimine)-co-poly(3,4-ethylenedioxythiophene) dendritic star copolymer (G2PPT-co-PEDOT). The morphological properties of the sensor platforms were interrogated by scanning emission microscopy (SEM) and atomic force microscopy (AFM), while their spectroscopic characteristics were studied by Fourier transform infra red spectroscopy (FTIR) and fluorescence spectroscopy. The electrochemical behaviour of the platforms and the aptasensors were studied by electrochemical impedance spectroscopy (EIS), cyclic voltammetry (CV) and square wave voltammetry (SWV). The DNA aptamer developed for detecting 17~-estradiol and which was used in the fabrication of all aptamer biosensors in this study is a 76-mer biotinylated aptamer (5'-BiotinGCTTCCAGCTTATTGAATTACACGCAGAGG TAGCGGCTCTGCGCATTCAATGCTGCGCGCTGAAGCGCGGAAGC-3'). AulPEDOTIAuNPslAptamer (platform 1) was obtained by covalently attaching streptavidin to the polymeric nanocomposite platform using carbodiimide chemistry and the aptamer immobilized via streptavidin-biotin interaction. The electrochemical signal generated from the aptamer-target molecule interaction was monitored electrochemically using cyclic voltammetry and square wave voltammetry in the presence of [Fe(CN)6J 3-/4- as a redox probe. The signal current observed was inversely proportional to the concentration of 17Bestradiol. The aptasensor demonstrated specificity toward 17~-estradiol. The detectable concentration range of the 17B estradiol was 0.01 nM-O .09 nM with a detection limit of 3.2 pM. The 76-mer biotinylated aptamer for 17~-estradiol was incorporated into a generation 1 poly(propylenethiophenoimine )-co-poly(3 ,4-ethylenedioxythiophene) dendritic star copolymer modified Au electrode via biotin-avidin interaction (platform 2). The Bode plot shows that the charge transfer dynamics of the nanoelectrode can be frequency modulated while the AulG 1PPTco- PEDOT nanoelectrode exhibited greater semi-conductor behavior (higher phase angle value) than AulG 1PPT due to the incorporation of charged functionalized dendrimer at low frequencies (100 mHz). The biosensor response to 17~-estradiol was based on the decrease in the SWV current as the EDC binds to the ssDNA aptamer on the biosensor. The dynamic linear range of the sensor was 0.01-0.07 nM with a detection limit of7.27 pM. Synthesis of electro synthetic generation G2PPT-co-PEDOT (platform 3) was performed by copolymerization of PEDOT with G2PPT dendrimer modified electrode immersed in a solution of 0.1 M LiCI04 containing 0.1 M EDOT monomer and 0.1 M sodium dodecyl sulphate (SDS) for ten (10) cycles. The electrochemical behaviour of the dendritic star copolymer was investigated with CV and EIS in LiCI04 and phosphate buffer solutions. The results show that the electrochemical deposition of G2PPT-co-PEDOT on gold electrode decreased the electrochemical charge transfer resistance when compared to AuiPEDOTILiCI04 and AuiLiCI04 interfaces. Bode impedimetric analysis indicates that G2PPT-co-PEDOT is a semiconductor. The fabrication of two novel aptasensors (based on platforms 2 and 3) simultaneously on a screen printed micro array electrode of 96-well multichannel electrochemical robotic sensor testing system for the detection of endocrine disrupting l7~-estradiol, was also carried out. The aptasensors responses to l7~-estradiol, based on the decrease in the SWV current, were evaluated.
402

Využití porézní aluminy pro přípravu nanostrukturovaných vrstev a jejich fotoelektrochemické a optické aplikace / Utilization of porous anodic alumina for fabrication of nanostructured layers and their photoelectrochemical and optical applications

Lednický, Tomáš January 2021 (has links)
Porézní anodická alumina (PAA) je oxidová vrstva vytvořená anodickou oxidací hliníku, která má široké průmyslné využití. Její popularita zaznamenala exponenciální nárůst zejména v oblasti nanotechnologií, k čemu přispělo objevení jejího samouspořádání do struktury o nanorozměrech připomínající včelí plástev. Její jednoduchá příprava a laditelné vlastnosti z ní tvoří levný způsob výroby nanostruktur. Ve stejném duchu se tato disertační práce zabývá metodami přípravy funkčních nanostruktur za využití PAA. První část je zaměřena na výrobu pole nanosloupců z oxidu titaničitého (TiO2) a jejich možné použití jako fotoanody pro štěpení vody. TiO2 nanostloupce jsou tvořeny anodizací hliníkové vrstvy na titanovém substrátu, také nazývanou PAA-asistovaná anodizace. Táto studie demonstruje elektrochemické vlastnosti a fotoelektrochemickou aktivitu nano sloupců vytvořených z dusíkem obohacených substrátů, které byly následně různě termálně modifikovány. Hlavním poznatkem studie je, že špatné vlastnosti jsou způsobeny dutou morfologií nanosloupců. Tento poznatek vedl k rozsáhle studii zabývající se dopadem anodizačných podmínek na morfologii ale i stabilitu vytvořených nanosloupců, jejímž výsledkem byla nová strategie anodizace. Druhá část prezentuje výrobní proces přípravy uspořádané vrstvy zlatých nanočástic na transparentním substrátu pro jejich použití jako optického senzoru využívající efekt rezonance lokalizovaných povrchových plasmonů. Základem této multidisciplinární metody je využití kombinace samouspořádání PAA k výrobě šablony a následného procesu řízeného smáčení v pevné fázi tenké vrstvy zlata. Táto práce detailně popisuje technologické aspekty přípravy; od samotné výroby šablon z hliníku, přes vytváření zlatých nanočástic, až po jejich přenos na transparentní substrát. Na závěr této práce jsou kompozity z nanočástic charakterizovány, přičemž je porovnána jejich citlivost na změnu indexu lomu okolí a jejich stálost. Ze závěrů vyplývá, že tato poměrně velkoplošná a levná metoda je konkurence schopná i v oblasti senzorické citlivosti.
403

Design of a no-wash colorimetric biosensor for the detection of the cancer biomarker Mdm2 with plasmonic nanoparticles

Retout, Maurice 13 November 2020 (has links) (PDF)
Today, development of accurate early diagnosis of cancers thus became the number one challenge of medicine during the 21st century as the current techniques relies on imaging methods that suffer from low sensitivity and misdiagnosis.For these reasons, in this work, we aimed at developing a no-wash colorimetric biosensor for the detection of the oncoprotein Mdm2. Indeed, abnormal levels of Mdm2 could be related to the early formation of tumors.This thesis is devoted to the conception of a no-wash colorimetric biosensor for the detection of the oncoprotein Mdm2. This work can be divided in four parts:(i) The detection strategy and the design of the recognition elements (Chapter I).(ii) The conjugation of gold nanoparticles with the recognition elements (Chapter II, III, IV, V and VI).(iii) The modification of the metallic core of the nanoparticles (Chapter VII).(iv) The use of the optimized biosensor for the detection of Mdm2 (Chapter VIII).In the first part, we investigated the sensing strategy. An aggregation-based assay with plasmonic nanoparticles was selected, as the detection signal is a change of color of the suspension that can be observed to the naked eye or by UV-Vis spectroscopy. We designed the recognition elements, two peptide aptamers coming from endogenous proteins p53 and p14, and we grafted them separately on two batches of gold nanoparticles (AuNPs) via thiol end-groups. We used these latter for the detection of various concentrations of Mdm2 in buffer using our dual-trapping strategy with these two batches of functionalized AuNPs. We demonstrated that both peptides are able to interact with Mdm2 even after grafting onto the particles and that this detection strategy is highly specific. However, this first sensor presented some drawbacks, such as a poor colloidal stability of the AuNPs and a limited dynamic range.With the aim to encompass these issues we investigated, in the second part of this thesis, alternative strategies to conjugate the peptides to the particles. We investigated the functionalization of the particles with stabilizing ligands such as thiolated poly(ethyleneglycol) (HS-PEG). We first studied their simultaneous grafting with the peptides on the AuNPs. We observed that grafting HS-PEGs and peptides side-by-side allowed to control the density of peptides conjugated to the AuNPS and increased drastically the stability of the particles. However, the detection of Mdm2 was strongly hindered by the presence of PEG on the particles carrying the p14 peptide. In a second step, we investigated the conjugation of peptides on the top of a PEG layer carrying functional groups (HS-PEG-X where X is a carboxylate or an alkyne). AuNPs were first functionalized with mixtures of HS-PEG and HS-PEG-X, and the peptides were conjugated to the functional groups via amide bond formation or CuAAC coupling in a second step. However, we noticed that it was not possible to control the composition of the mixed layer of PEGs and thus the peptide grafting density.Due to the lack of recognized protocols in the literature for (i) the determination of the chemical and colloidal stabilities of AuNPs and (ii) the determination of the proportion of different ligands in the organic coating of the particles, we developed two interesting tools. The first one was a convenient method allowing to evaluate by UV-Vis spectroscopy the efficiency of the citrate exchange process using thiol-, alkyne- or diazonium-ligands from gold nanoparticles synthesized via a Turkevich method. The second protocol was a method allowing to quantify the proportion of two HS-PEGs ligands grafted in mixtures onto gold nanoparticles via 1H NMR spectroscopy.As we couldn’t find conditions in which the proportion of multiple thiolated ligands can be controlled on AuNPs, we decided to investigate another functionalization strategy based on the use of calix4arene-diazonium salts.We first studied the grafting on AuNPs of calixarenes bearing four PEG chains at the level of their small rim, one ended by a carboxylic acid and three by a methoxy group. The calixarene layer allowed to obtain AuNPs covered by a very dense PEG shell (with more PEG chains/nm2 that what was obtained previously with thiol anchoring). In addition to that, this PEG shell was strongly anchored to the AuNPs, conferring them a very high colloidal and chemical robustness. We then combined the grafting of this calixarene with the grafting of another non-functional calixarene, bearing four PEG chains ended by a methoxy group, and we quantified the conjugation capacity of such particles by amide bond formation. We demonstrated that this strategy allows to (i) increase drastically the stability of the AuNPs and (ii) control the proportion of peptide conjugated at their surface. Finally, we showed that calixarene-coated AuNPs to which to the p53 and p14 peptides have been conjugated could be used to detect Mdm2.With the evidence that the peptide conjugation density could be controlled using calixarene-coated AuNPs, we investigated the simultaneous grafting of two functional calixarenes on particles: one bearing four carboxylic acids groups and one bearing four PEG chains ended by alkyne groups. We optimized the grafting of these calixarenes in mixed layers on the AuNPs as well as their conjugation. We demonstrated that the grafting of two functional calixarenes led to the production of bi-functional AuNPs, capable of conjugation with two molecules via two distinct chemistries.In the third part, we optimized the composition of the metallic core of the biosensor. As it is well known that silver nanoparticles express better optical properties than gold nanoparticles of the same size, we aimed to incorporate silver nanoparticles (AgNPs) in the biosensor. This was a true challenge due to the intrinsic low chemical stability of silver nanoparticles that greatly limits their use in IVD. For this purpose, we developed an innovative in situ synthesis of silver nanoparticles in the presence of the calixarene-diazonium salts. After optimization of the synthesis, we observed that calixarenes bearing four carboxylic acids groups at the level of their small rim allowed the production of ultra-stable silver nanoparticles to which biomolecules can easily be conjugated. This in situ synthesis procedure even allowed us to produce alloy nanoparticles, with metallic cores whose composition could easily be tuned from pure silver to silver/gold alloys or pure gold. With this synthesis, the composition of the organic layer could also be easily tuned by using mixtures of calixarenes-diazonium salts.Finally, in the last part, we investigated the detection of Mdm2 with the optimized version of the biosensor, i.e. silver nanoparticles coated by a calixarene layer to which the p53 and p14 peptides were conjugated. With this novel class of nanoparticles, we could encompass the two initial drawbacks of the initial sensor. First, we were able to detect Mdm2 with a wider detection range and a lower limit. Secondly, the particles were sufficiently stable and robust to be dispersed in physiological fluids and we could detect Mdm2 in human serum without interference. / Doctorat en Sciences de l'ingénieur et technologie / info:eu-repo/semantics/nonPublished
404

Films polymériques pour le développement de stents innovants / Polymeric films for innovative stent development

Pallotta, Arnaud 08 December 2017 (has links)
La prise en charge en urgence des pathologies ischémiques repose dans un premier temps sur la thrombolyse et/ou l’angioplastie puis dans un second temps sur des mesures hygiéno-diététiques. L’angioplastie consiste en la destruction de l’obstacle situé dans l’artère et elle est souvent suivie (dans 70 % des cas) par la pose d’une endoprothèse ou stent afin que le vaisseau lésé retrouve son diamètre. Malgré des innovations thérapeutiques (stents libérant des principes actifs), des problèmes de thrombose et de resténose au niveau du site lésé sont observés. Or, le monoxyde d’azote, NO, un gazotransmetteur de l’organisme, possède des propriétés intéressantes (antiagrégant plaquettaire, effet de recrutement des cellules endothéliales, effet antiprolifératif sur les cellules musculaires lisses) pour lutter contre ce phénomène, à concentration physiologique. Dans ce travail, nous avons développé une formulation innovante pouvant recouvrir un stent et étant capable de délivrer du NO. Il s’agira d’incorporer des nanoparticules d’or caractérisées par une capacité de greffage par un donneur de NO (AuNP@RSNO) très importante au sein des couches d’un film constitué de polyélectrolytes (polycations et polyanions interagissant de façon électrostatique). Ici, les AuNP sont considérées comme une matière première pharmaceutique. Une méthode de dosage et un contrôle qualité de ces dernières ont donc été développés. Les films créés présentent une stabilité importante (> 1 an) et sont capables d’immobiliser un grand nombre d’AuNP (1012 AuNP/cm²/cycle). Pour augmenter le taux de chargement des AuNP au sein des films, l’optimisation de leur construction a été réalisée. Plusieurs polycations ont été testés (chlorhydrate de poly(allylamine), poly(éthylène glycol) et poly(méthacrylate d’ester)) ainsi que deux milieux de dissolution différents (tampon phosphate et tampon Tris, à pH et concentrations identiques). Le meilleur rapport stabilité/taux de chargement a été atteint avec l’utilisation du chlorhydrate de poly(allylamine) et le tampon Tris. Enfin, les films ont présenté une inertie face à des protéines, des cellules et du sang total. Le système développé représente donc une forme adaptée pour être déposé à la surface de stents / Emergency management of ischemic pathologies is initially based on thrombolysis and / or angioplasty and secondly on hygiene-dietetic measures. Angioplasty consists of the destruction of the obstacle located in the artery and is often followed (in 70% of cases) by placing a stent so that the damaged vessel regains its diameter. Despite therapeutic innovations (drug eluting stents), problems of thrombosis and restenosis in the injured site are often observed. However, nitric oxide, NO, has interesting properties (platelet antiaggregant, endothelial cell recruitment effect, antiproliferative effect on smooth muscle cells) against this phenomenon at physiological concentration. In this work, we developed an innovative formulation that can deposited on a stent and that will be able to deliver NO. AuNP grafted with a high density of NO donors (AuNP@RSNO) will be incorporated in layer-by-layer films composed of polyelectrolytes (electrostatic interactions between polycations and polyanions) Here AuNPs are considered as a pharmaceutical raw material. A quantification method and a quality control of them were therefore developed. Created films created showed an important stability (> 1 year) and were able to immobilize a large number of AuNP (1012 AuNP/cm²/cycle). In order to increase the loading rate of AuNP films, optimization of their construction was carried out. Several polycations were tested (poly (allylamine hydrochloride), poly (ethylene glycol) and poly (methacrylate ester)) as well as two different dissolution media (phosphate buffer and Tris buffer, same pH and concentrations). The best stability/loading ratio was achieved with the use of poly (allylamine) hydrochloride and Tris buffer. Finally, the films showed inertness when they were exposed to proteins, cells and whole blood. The developed system is therefore well suited to be deposited on the surface of stents
405

Élaboration par ablation laser en milieu liquide de nanoparticules métalliques : caractérisation et modélisation des réponses plasmoniques des nanoparticules d’or et d’argent / Generation of metallic nanoparticles by Pulsed-Laser Ablation in Liquids : Characterization and modelling of the plasmonics responses of gold and silver nanoparticles

Resano-Garcia, Amandine 30 November 2016 (has links)
Les nanoparticules métalliques (NPs) présentent des propriétés optiques (PO) uniques provenant de l’oscillation collective de leurs électrons. Cet effet se traduit par l'émergence d'une bande plasmon dont les caractéristiques peuvent être modulées par la taille, la forme, la nature des NPs et le milieu hôte. Il existe de nombreuses méthodes pour la préparation de ces NPs, l'une d'entre elles est l'ablation laser en milieu liquide (ALML). Cette technique offre certains avantages comme la simplicité, l’adaptabilité et des NPs dépourvues de contamination. Ses principaux inconvénients sont la productivité et le contrôle de la taille et de la forme des NPs. Ce travail est consacré à l'élaboration de NPs d’Ag par l’ALML et à l'étude théorique de leurs PO. Nous donnons dans ce manuscrit, les résultats de l'optimisation des paramètres d'élaboration conduisant à l'obtention de distributions en NPs reproductibles et contrôlées. Les PO de ces NPs sont mesurées et comparées à des modèles physiques spécifiques basés sur la théorie des milieux effectifs (EMT). L'EMT, telle que le modèle de Maxwell-Garnett, permet de décrire les PO de NPs monodisperses. Cependant, les voies de préparation classiques conduisent inévitablement vers des NPs montrant une distribution de forme et de taille qui induit des changements drastiques sur leurs PO. Le modèle SDEMT est proposée pour le calcul de la fonction diélectrique effective et du coefficient d'absorption de solutions colloïdales de NPs métalliques. Contrairement à Maxwell-Garnett, ce modèle donne une meilleure description des spectres d'absorption et d’ellipsométrie mesurés sur des échantillons contenant des NPs d’Ag et d’Au / Metal nanoparticles (NPs) exhibit unique optical properties (OP) coming from the collective oscillations of their electrons. This effect is translated by the emergence of a band of plasmon, the characteristics which can be modulated by the size, the shape and the nature of the NPs as well as by the environment of the host. There are many methods for the preparation of NPs, and one of them is the pulsed-laser ablation in liquid (PLAL). This technique offers some advantages such as simplicity, versatility and surface NP without contamination (reducing agent residues and/or stabilizers). Its main drawbacks are the lacks of productivity and control of the NP size and shape. This work is devoted to elaboration of Ag NPs by PLAL and theoretical investigation of their OP. We give here the results about the optimization of elaboration parameters leading to obtaining reproducible and controlled distributions of Ag NPs. The OP of these NPs are measured and compared to specific physical models based on the effective medium theory (EMT). Classical EMT such as Maxwell Garnett approximation allows describing the OP of monodisperse NPs. However, conventional preparation routes unavoidably conduct to NPs showing a shape and a size distribution which induces drastic changes in the OP. A SDEMT model which considers the shape dispersion is proposed for the calculation of the effective dielectric function and absorption coefficient of colloidal solution of metal NPs in water. Contrary to the conventional theory, this model gives a better description of the measured absorption and ellispometry spectra of sample containing Ag and Au NPs
406

Understanding the impact of engineered nanoparticles Gammarus sp. as a valuable non-vertebrate model? / Compréhension de l'impact des nanoparticules manufacturées : intérêt du gammare comme modèle invertébrés ?

Mehennaoui, Kahina 20 December 2017 (has links)
La toxicité potentielle des nanomatériaux présente un intérêt sociétal et scientifique élevé en raison de la promesse d'innovations pour de nombreuses applications techniques. Cependant, elle n’est pas forcément liée à la taille réelle, à la masse, à la surface des nanoparticules (NP) ou à leurs agglomérats. La toxicité des NPs pourrait être fortement influencée par d'autres propriétés inhérentes et encore incomprises telles que le relargage d’ions, de la particule elle-même, sa surface, ou des molécules adhérentes à la surface, qui interfèreraient avec l'absorption cellulaires des NPs. Le projet « NANOGAM» étroitement lié au projet « FNR CORE2012 NANION », vise à définir certains processus et facteurs impliqués dans l'absorption des NPs et leur toxicité. Une telle compréhension est une condition préalable au développement des nanomatériaux, fondement de la philosophie « safer-by-design ». Les objectifs de ce projet de thèse sont multiples. En tenant compte des caractéristiques des principaux paramètres physico-chimiques tels que la taille et l’aspect de la surface, l’étude a porté sur l'absorption de NPs d'argent et d'or, et leurs effets biologiques via une approche multi-biomarqueurs (mortalité, effets comportementaux, effets physiologiques, effets transcriptomiques, etc.) sur une espèce sensible, Gammarus fossarum (Crustacea Amphipoda). Le but de cette investigation est de comprendre si la toxicité des nanomatériaux est inhérente aux propriétés intrinsèques des NPs ou plutôt aux ions relargués, ce qui contribuera à la prédiction de la toxicité des NPs en rapport avec leurs propriétés physico-chimiques et ce afin de limiter le nombre d’essais répétitifs sur de nouveaux nanomatériaux. G. fossarum ont été exposés à de faibles concentrations d'AgNPs et AuNPs pendant 72h à jeun et 15 jours nourris. Les résultats obtenus ont montré que (i) la nature de l’enrobage de surface est le principal facteur responsable de l'absorption d'AgNPs et d'AuNPs par G. fossarum ; (ii) les ions libérés et les NPs elles-mêmes jouent un rôle dans la toxicité des AgNPs et AuNPs étudiées ; (iii) la composition chimique des NPs a conduit à des effets différents aux niveaux sub-individuels (transcriptomique), ainsi qu’à une distribution différente dans les tissues selon la nature métallique de la NP. Les AgNPs ont été localisées dans les branchies de G. fossarum tandis que les AuNPs ont été observées dans les caeca intestinaux. Cette étude a également révélé que Gammarus sp. est un excellent modèle pour l'étude de la toxicité et des effets des AgNPs et des AuNPs / The potential toxicity of nanomaterials is of high societal and scientific interest due to the promise of ground-breaking innovations for many technical applications. However, toxicity can often not be related to the actual size, mass or surface area of the single nanoparticles (NPs) or the NP agglomerates. Therefore, it can be proposed that the toxicity is greatly influenced by other inherent and non-understood properties of the particles to which ions dissolving from the particle, surface or molecules adhering to the surface interfering with the uptake of NPs into cells, may have important contributions. The PhD project “NANOGAM”, closely linked up to CORE2012 NANION project that aims to obtain knowledge to understand some of the processes and factors involved in NP uptake and toxicity as such understanding is a prerequisite for the development of nanomaterials following the safer-by-design philosophy. This PhD project aims to investigate, based on known characteristics of the key physico-chemical parameters; as size and surface functionalities, of a well-chosen list of silver and gold NPs, the uptake, and dependent biological effects of different complexity (mortality, behavioural effects, physiological effects, transcriptomic effects, etc.), on a sensitive species; Gammarus fossarum (Crustacea Amphipoda), in order to understand to which extent toxicity of nanomaterials is due to intrinsic material properties or ion leaching. Such understanding will contribute to the prediction of toxicity based on material properties rather than repetitive testing of an indefinite number of new nanomaterials. G. fossarum were exposed at low concentrations of AgNPs and AuNPs for 72h or 15 days in presence or absence of food. The obtained results showed that (i) surface coating is the main factor governing AgNPs and AuNPs uptake by G. fossarum, (ii) both released ions and NPs themselves play a role in the potency of the studied AgNPs and AuNPs and (iii) chemical composition led to different effects at the sub-individual levels (target genes expression) and different tissue distribution as AgNPs were found in G. fossarum gills while AuNPs were found in the intestinal caeca. Additionally, this work shows that Gammarus sp. are valuable models for the study of the effects of AgNPs and AuNPs
407

Application of Single Optically Heated Gold Nanoparticles to Sensing and Actuation

Heber, André 07 December 2017 (has links)
Diese Dissertation demonstriert die Nutzung von einzelnen optisch geheizten Goldnanopartikeln als Sensoren f ¨ur die Untersuchung von W¨armetransport und als Intensit¨atsmodulator f ¨ur Licht. Die beschriebenen Experimente basieren auf der photothermischen Mikroskopie, die die selektive Abbildung and Untersuchung von einzelnen absorbierenden Objekten erm¨oglicht. Goldnanopartikel werden optisch angeregt. Die Relaxation erfolgt durch nichtstrahlende Prozesse, die zu einer lokalen Erh¨ohung der Temperatur f ¨uhren. Die Erw¨armung f ¨uhrt zu einer Verringerung der Brechzahl, die als thermische Linse wirkt und dadurch die Ausbreitung eines zweiten nicht absorbierten Lichtstrahls vera¨ndert. Da die thermische A¨ nderung der Brechzahl sehr gering ist, wird das photothermische Signal durch das moduliertes Detektionsverfahren verst¨arkt. Der Heizlaserstrahl wird intensit¨atsmoduliert und erzeugt dadurch eine geringe Modulation der Strahlbreite des Detektionslaserstahls. Damit ver¨andert sich die Leistung, die durch eine Blende transmittiert wird. Diese Modulationsamplitude and Phaseverz¨ogerung werden mittels eines phasenempfindlichen Gleichrichters detektiert. Amplitude und Phase h¨angen von Modulationsfrequenz und thermischer Diffusivit¨at ab. Die frequenzaufgel¨oste Messung der beiden Gr¨oßen und deren Modellierung mittels einer verallgemeinerten Lorenz–Mie Theorie erm¨oglicht die Messung von der thermischen Diffusivit¨at des Mediums, das das Goldnanopartikel umgibt. In der zweiten Variante wird die Ausbreitung der W¨arme beobachtet. Ein Nanopartikel wird optisch geheizt und die ausgedehnte thermische Linse wird mit Hilfe der Ablenkung eines zweiten Laserstrahls vermessen. Das Ablenkungssignal wird mittels eines strahlenoptischen Models berechnet, um die thermische Diffusivit ¨at des Materials zu bestimmen, das das Nanopartikel umgibt. In einem weiteren Experiment wird das große Potential von optisch geheizten Nanopartikeln verdeutlicht. Einzelne Goldnanopartikel werden in eine d¨unne nematische Fl¨ussigkristallschicht eingebettet, deren Dicke darauf abgestimmt ist, dass die Schicht eine l/2-Platte darstellt. Die Goldnanopartikel werden optisch geheizt und steuern damit den Phasen¨ubergang von der nematischen zur isotropen Phase. Damit wird die Transmission eines zweiten Laserstrahls im Polarisationskontrast ge¨andert. Mit Hilfe dieser Anordnung kann die Intensit¨at eines Lichtstrahls um bis zu 100% moduliert werden. / This dissertation demonstrates the use of individual optically heated gold nanoparticles as sensors for investigations of heat transport and intensity modulation of light. The experiments employ the photothermal effect, which allows the selective detection and investigation of individual absorbers. The photothermal contrast is based on absorbing particles that are optically excited and relax via nonradiative processes. The absorbers act as nanosources of heat. The local temperature elevation leads to a local refractive index change due to thermal expansion which then acts as a lens. This thermal lens alters the propagation of a second non-absorbed beam of light. As the refractive index change with temperature is minuscule, the transmission changes of the detection are tiny as well. The photothermal signal is amplified by the use of a modulated detection scheme which enables the methods high sensitivity and provides a time scale for the measurement of thermal transport. The heating laser beam is intensity-modulated and thereby produces a small modulation of the beam waist of the detection laser beam and thus the transmitted power through an aperture. This modulation amplitude and phase are detected by a lock-in amplifier. Amplitude and phase depend on the modulation frequency and the thermal diffusivity of the material surrounding the nanoparticle. The frequency-resolved measurement of the two observables and their modeling using a generalized Lorenz–Mie theory allows the measurement of thermal diffusivities. In the second variant, the spread of heat into space is observed. A nanoparticle is optically heated, and the extended thermal lens is characterized by the deflection of a second laser beam. The deflection signal is modeled using ray optics to determine the thermal diffusivity of the material surrounding the nanoparticle. In a further experiment, the great potential of optically heated nanoparticles is demonstrated. Individual gold nanoparticles are embedded in a thin nematic liquid-crystal layer acting as a half-wave plate. The gold particles are optically heated. They control the transmission of a detection laser set up in polarization contrast. The intensity of the detection beam is modulated by up to 100%.
408

Yolk-Shell Nanostructures Prepared via Block Copolymer Self-Assembly for Catalytic Applications

Shajkumar, Aruni 19 January 2018 (has links)
Yolk-shell nanostructures/yolk-shell nanoparticles are defined as a hybrid structure, a mixture of core/shell and hollow particles, where a core particle is encapsulated inside the hollow shell and may move freely inside the shell. Of the various classifications of yolk-shell nanostructures, a structure with an inorganic core and inorganic shell (inorganic/inorganic) has been studied widely due to their unique optical, magnetic, electrical, mechanical, and catalytic properties. In the work presented here, among the different inorganic/inorganic yolk-shell nanostructures noble metal@silica yolk-shell nanostructures has been chosen as the topic of interest. Silica shell possesses many advantages such as chemical inertness, tunable pore sizes, diverse surface morphologies, increasing suspension stability, no reduction in LSPR properties of noble metal nanoparticles when used as a coating for such particles. Noble metal nanoparticles such as AgNPs and AuNPs, on the other hand, possess unique structural, optical, catalytic, and quantum properties. Hence yolk-shell nanostructures with a combination of Ag or Au core and a silica shell (Ag@SiO2 and Au@SiO2) would open to endless possibilities. In this study, four areas were mainly explored: mechanism of silica shell formation over a given template, the synthetic modifications of Ag@SiO2 and Au@SiO2 yolk-shell nanostructures, their application as a potential catalyst, and devising of a flow type catalytic reactor. Despite the growing number of contributions on the topic of yolk-shell nanostructures, particularly Au@SiO2 and Ag@SiO2 yolk-shell nanostructures, a potential for improvement lies in all four aforementioned areas. As an initial study, the effect of different processing conditions as well as the mechanism of silica shell formation over reactive block copolymer templates was investigated. An asymmetric PS-b-P4VP block copolymer was chosen as a structure directing component to deposit silica shell. In order to deposit silica shell, PS-b-P4VP micelles with a collapsed PS core and a swollen P4VP corona was prepared via a solvent exchange method. The growth of silica shell over the PS-b-P4VP micelles (reactive template) was done using in-situ DLS and TEM. The experimental data obtained revealed the 4 distinct stages involved in the silica shell formation over the reactive BCP micellar template starting from the accumulation of silica precursor around the P4VP corona followed by a reactive template mediated hydrolysis-condensation reaction of the silica precursor which eventually lead to the shell densification and shell growth around the micelles. An understanding of the mechanism of silica shell formation over reactive templates provides a direct way to encapsulate various active species such as metal nanoparticles and quantum dots and paves the way for the template mediated synthesis of hybrid nanostructures such as yolk-shell nanoparticles. These studies also serve as a platform to fine-tune the properties of such hybrid nanostructures by varying the reaction parameters during silica shell deposition and reaction time. The next part of the work focused mainly on the synthesis, process optimisation and characterization of Ag@SiO2 and Au@SiO2 yolk-shell nanostructures, and their potential use as a nanocatalyst. A well-known soft template mediated synthesis of the yolk-shell nanostructure was adopted for the present work. For this PS-b-P4VP micelle was used as a dual template for both encapsulation of nanoparticle and the deposition of silica shell. The nanoparticles were entrapped selectively to the BCP micellar core and silica deposition was done by reacting the nanoparticle-loaded micelles with an acidic silica sol which lead to the formation of Ag@PS-b-P4VP@SiO2 or Au@PS-b-P4VP@SiO2 particles with respect to the nanoparticle used. In the case of Ag@PS-b-P4VP particles, upon silica deposition, a partial dissolution of AgNPs was observed whereas AuNPs were stable against dissolution. Hence yolk-shell nanostructures with AuNPs were studied further. As-prepared Au@PS-b-P4VP@SiO2 particles were then subjected to pyrolysis to remove the BCP template. The resulting yolk-shell nanostructures comprised of an AuNP core and a hollow mesoporous silica shell. Upon removal of the BCP template, the Au@SiO2 particles fused together and formed large aggregates. The catalytic properties of Au@SiO2 yolk-shell nanoparticles were explored using a model reaction of reduction of 4-nitrophenol and proved to have good catalytic activity and efficient recyclability. It was observed that catalytic efficiency was hindered by the particle aggregates formed after pyrolysis by creating an inhomogeneity in the system and inaccessibility of the catalytic surface for the reactants. Hence synthetic modifications were needed to overcome such drawbacks. Next part of the work deals with the synthetic modification of Au@SiO2 yolk-shell nanoparticles done by embedding them in a porous silica structure (PSS). Such structural morphology was attained by gelating the excess silica precursor while synthesising the Au@PS-b-P4VP@SiO2 particles. The pyrolytic removal of block copolymer results in the formation of Au@SiO2@PSS catalyst and the porous nature of both the shell and the silica structure provides an easy access for the reactants to the nanocatalyst surface located inside. The catalytic properties of Au@SiO2@PSS were studied using a model reaction of catalytic reduction of 4-nitrophenol (4-NP) and reductive degradation of different dyes. Kinetic studies show that Au@SiO2@PSS catalyst possesses enhanced catalytic activity as compared to other analogous systems reported in the literature so far. Furthermore, catalytic experiments on the reductive degradation of different dyes show that Au@SiO2@PSS catalyst can be considered as a very promising candidate for wastewater treatment. Another proposed direction of applying the Au@SiO2 yolk-shells is by devising a continuous flow catalytic system composed of Au@SiO2 yolk-shell nanoparticles for the effective degradation of azo dyes as a promising candidate for wastewater treatment. This was done by infiltrating the Au@PS-b-P4VP@SiO2 particles inside a porous glass substrate (frits) and the subsequent pyrolytic removal of the BCP template resulting in the formation of Au@SiO2 yolk-shell nanostructures sintered inside the frit pores. The flow catalytic reactor was exploited in terms of studying its catalytic activity in the degradation of azo dyes and 4-nitrophenol and proved to have a catalytic efficiency of ca. 99% in terms of reagent conversion and has a long-term stability under flow. Thus, with a few modifications, these flow type systems can open the doors to a very promising continuous flow catalytic reactor in the future.
409

Synthesis of Functional Block Copolymers for use in Nano-hybrids

Ibrahim, Saber 22 March 2011 (has links)
Polystyrene block polyethyleneimine (PS-b-PEI) copolymer prepared by combining PS and poly(2-methyl-2-oxazoline) (PMeOx) segments together through two strategies. Furthermore, PMeOx block was hydrolysis to produce PEI block which linked with PS block. Macroinitiator route is one of these two ways to prepare PS-b-PEI copolymer. Polystyrene macroinitiator or poly(2-methyl-2-oxazoline) macroinitiator prepared through Nitroxide Mediate Radical Polymerization (NMRP) or Cationic Ring Opening Polymerization (CROP) respectively. Each macroinitiator has active initiated terminal group toward another block monomer. Second strategy based on coupling of PS segment with PMeOx block through “click” coupling chemistry. Polystyrene modified with terminal azide moiety are combined with PMeOx functionalized with alkyne group via 1,3 dipolar cycloaddition reaction “click reaction”. PS-b-PMeOx was hydrolysis in alkaline medium to produce amphiphilic PS-b-PEI copolymer. A set of block copolymer with different block ratios was prepared and investigated to select suitable block copolymer for further applications. Stichiometric PS-b-PEI copolymer selected to stabilize gold nanoparticle (Au NPs) in polymer matrix. PEI segment work as reducing and stabilizing agent of gold precursor in aqueous solution. Various concentrations of gold precursor were loaded and its effect on UVVIS absorbance, particle size and particle distribution studied. In addition, reduction efficiency of PEI block was determined from XPS measurements. The thickness of Au NPs/PS-b-PEI thin film was determined with a novel model for composite system. On the other hand, Gallium nitride quantum dots (GaN QDs) stabilized in PS-b-PEI copolymer after annealing. Our amphiphilic block copolymer exhibit nice thermal stability under annealing conditions. GaN QDs prepared in narrow nano-size with fine particle distribution. Blue ray was observed as an indication to emission activity of GaN crystal. Over all, PS-b-PEI copolymer synthesized through macroinitiator and click coupling methods. It was successfully stabilized Au NPs and GaN QDs in polymer matrix with controlled particle size which can be post applied in tremendous industrial and researcher fields.
410

Hydrophob/hydrophil schaltbare Nanoteilchen für die Biomarkierung

Dubavik, Aliaksei 15 July 2011 (has links)
There is a demand for new straightforward approaches for stabilization and solubilization of various nanoparticulate materials in their colloidal form, that pave way for fabrication of materials possessing compatibility with wide range of dispersing media. Therefore in this thesis a new general method to form stable nanocrystals in water and organics using amphiphilic polymers generated through simple and low cost techniques is presented and discussed. Amphiphilic coating agents are formed using thiolated or carboxylated polyethylene glycol methyl ether (mPEG-SH) as a starting material. These materials are available with a wide variety of chain lengths. The method of obtaining of amphiphilic NPs is quite general and applicable for semiconductor CdTe nanocrystals as well as nanoscale noble metal (Au) and magnetic (Fe3O4) particles. This approach is based on anchoring PEG segment to the surface of a nanoparticle to form an amphiphilic palisade. Anchoring is realized via interaction of –SH (for CdTe and Au) or –COOH (in the case of magnetite) functional groups with particle’s surface. The resulting amphiphilicity of the nanocrystals is an inherent property of their surface and it is preserved also after careful washing out of solution of any excess of the ligand. The nanocrystals reversibly transfer between different phases spontaneously, i.e. without any adjustment of ionic strength, pH or composition of the phases. Such reversible and spontaneous phase transfer of nanocrystals between solvents of different chemical nature has a great potential for many applications as it constitutes a large degree of control of nanocrystals compatibility with technological processes or with bio-environments such as water, various buffers and cell media as well as their assembly and self-assembly capabilities.

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