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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.
61

Funktionalisierte Polymerkomposite auf Basis von Poly(3,4-ethylendioxythiophen) und Gold

Hain, Jessica 29 April 2008 (has links) (PDF)
Poly(3,4-ethylenedioxythiophene), PEDOT, belongs to the group of conducting polymers and is characterized by its high stability, a moderate band gap and its optical transparency in the conductive state. A large disadvantage of conducting polymers, and also PEDOT, is their poor solubility. One way to achieve processible materials is the synthesis of colloidal particles. Thus, this work focuses on the development of conductive particles by preparing composite structures. Polymeric colloids like latex particles and microgels were used as templates for the oxidative polymerization of EDOT. Depending on template structure completely different composite morphologies with variable properties were obtained. It was found that modification with PEDOT did not only cause conductive particles for application as humidity sensor materials, but also candidates for further functionalization with gold nanoparticles (Au-NPs). Due to a multi-stage synthesis route it was possible to achieve polystyrene(core)-PEDOT(shell)-particles decored with Au-NPs. Microgels acting as “micro reactors” for the incorporation of PEDOT and Au-NPs were also used for preparing multifunctional composites for catalytic applications. / Poly(3,4-ethylendioxythiophen), PEDOT, gehört zur Gruppe der leitfähigen Polymere und zeichnet sich durch seine hohe Stabilität, eine moderate Bandlücke und seine optische Transparenz im dotierten Zustand aus. Ein Nachteil leitfähiger Polymere, wie auch von PEDOT, ist deren schlechte Löslichkeit. Die Synthese kolloidaler Partikel bietet jedoch eine Möglichkeit dieses Problem zu umgehen. In diesem Zusammenhang richtete sich der Fokus dieser Arbeit auf die Darstellung leitfähiger Partikel in Form von Kompositstrukturen. Polymerkolloide, wie Latex- und Mikrogelpartikel, sind als Template eingesetzt worden, in deren Gegenwart PEDOT durch eine oxidative Polymerisation synthetisiert wurde. In Abhängigkeit von der Struktur des Templats sind unterschiedliche Kompositmorphologien mit steuerbaren Eigenschaften erhalten worden. Auf diese Weise wurden neben Materialien für die Feuchtigkeitssensorik leitfähige Kompositpartikel hergestellt, die zusätzlich mit Gold-Nanopartikeln (Au-NP) funktionalisiert werden konnten. Durch ein mehrstufiges Syntheseverfahren sind somit Polystyrol(Kern)-PEDOT(Schale)-Partikel mit Au-NP-funktionalisierter Oberfläche synthetisiert worden. Mikrogelpartikel, die als „Mikroreaktoren“ für die Inkorporation von PEDOT- und Au-NP dienten, wurden ebenfalls eingesetzt, um multifunktionale Komposite mit katalytischen Eigenschaften herzustellen.
62

Therapeutic Peptide-functionalized Gold Nanoparticles for the Treatment of Acute Lung Injury

Lee, Dai Yoon 03 December 2013 (has links)
Acute lung injury (ALI) is a major cause of mortality after lung transplantation. Recent studies indicate protein kinase C delta (PKCδ) could be an effective target to treat ALI. We have developed a gold nanoparticle (GNP)-peptide hybrid that can inhibit PKCδ signaling. PKCδ inhibitor peptide (PKCi) and 95P2P4 stabilizing peptides were conjugated onto GNP. Physicochemical properties of the nanoformulations were examined. A lung transplant-simulated cell culture model was used to evaluate therapeutic efficacy in vitro. A pulmonary ischemia-reperfusion (IR) model was used to test therapeutic efficacy in vivo. GNP-Peptide hybrids showed good stability with high cellular uptake. GNP-PKCi formulations demonstrated anti-inflammatory and anti-apoptotic effects in vitro. When administered to rats under IR stress, GNP-PKCi formulation improved blood oxygenation, reduced pulmonary edema and histological lung injury. In conclusion, we have successfully formulated a clinically-applicable nanoparticle with therapeutic potential to ameliorate lung injury and inflammation. Our formulation strategy could be used to deliver other peptide-based drugs.
63

Therapeutic Peptide-functionalized Gold Nanoparticles for the Treatment of Acute Lung Injury

Lee, Dai Yoon 03 December 2013 (has links)
Acute lung injury (ALI) is a major cause of mortality after lung transplantation. Recent studies indicate protein kinase C delta (PKCδ) could be an effective target to treat ALI. We have developed a gold nanoparticle (GNP)-peptide hybrid that can inhibit PKCδ signaling. PKCδ inhibitor peptide (PKCi) and 95P2P4 stabilizing peptides were conjugated onto GNP. Physicochemical properties of the nanoformulations were examined. A lung transplant-simulated cell culture model was used to evaluate therapeutic efficacy in vitro. A pulmonary ischemia-reperfusion (IR) model was used to test therapeutic efficacy in vivo. GNP-Peptide hybrids showed good stability with high cellular uptake. GNP-PKCi formulations demonstrated anti-inflammatory and anti-apoptotic effects in vitro. When administered to rats under IR stress, GNP-PKCi formulation improved blood oxygenation, reduced pulmonary edema and histological lung injury. In conclusion, we have successfully formulated a clinically-applicable nanoparticle with therapeutic potential to ameliorate lung injury and inflammation. Our formulation strategy could be used to deliver other peptide-based drugs.
64

Fator de aumento de dose em Radioterapia com nanopartículas: estudo por simulação Monte Carlo / Dose enhancement factor in radiation therapy with nanoparticles: a Monte Carlo simulation study.

Vinicius Fernando dos Santos 29 November 2017 (has links)
A incorporação de nanopartículas metálicas em tecidos tumorais tem sido estudada em Radioterapia devido ao aumento de dose que pode ser obtido no volume alvo do tratamento. Estudos indicam que nanopartículas de ouro (AuNP) estão entre as de maior viabilidade biológica para essas aplicações, devido ao baixo potencial tóxico. Além disso, estudos mostram que AuNP de alguns nanômetros até alguns micrômetros podem permear vasos sanguíneos que alimentam tumores, permitindo sua incorporação nas células tumorais. Desta forma, este trabalho visou estudar os fatores de aumento de dose obtidos em Radioterapia com AuNP incorporadas ao tecido tumoral utilizando feixes de ortovoltagem, de braquiterapia e de teleterapia. Este trabalho utilizou de uma metodologia computacional, através de simulação Monte Carlo com o código PENELOPE. Foram simulados feixes clínicos de 50, 80, 150 e 250 kVp, Ir-192 e 6 MV, e um modelo de célula tumoral com AuNPs incorporadas com diferentes concentrações de ouro. O modelo de células utilizado possui 13 µm de diâmetro externo máximo e 2 µm de diâmetro no núcleo. Dois modelos de incorporação de AuNPs foram implementados: modelo homogêneo e modelo heterogêneo. No modelo homogêneo, as AuNP foram distribuídas homogeneamente no núcleo e as células foram irradiadas nas diferentes energias estudadas para avaliar o fator de aumento de dose (DEF) em função da concentração de ouro na célula e da energia do feixe. No modelo heterogêneo, aglomerados de AuNPs foram simulados individualmente dentro da célula. Neste modelo foram utilizados somente os espetros de radiação que apresentaram os melhores desempenhos no modelo homogêneo. Foram avaliadas a fluência de partículas ejetadas nas AuNPs, o DEF, as distribuições de doses e os perfis de dose com aglomerados de 50 a 220 nm na célula. Os resultados obtidos para o modelo homogêneo mostram que os feixes de baixa energia são os que proporcionam maior DEF para uma mesma concentração de AuNP. Os maiores DEFs obtidos foram de 2,80; 2,99; 1,62 e 1,61, para os feixes de 50 kVp, 80 kVp, 150 kVp, 250 kVp, respectivamente, sendo a maior incerteza de 1,9% para o feixe de 250 kVp. Através dos resultados obtidos com o modelo heterogêneo foi possível concluir que os elétrons ejetados possuem maior influência no aumento local da dose. Os perfis de dose, extraídos das distribuições de doses, para os aglomerados simulados permitiram obter os alcances das isodoses de 50, 20 e 10% da dose no entorno das AuNPs. Através desses perfis de dose pode-se concluir que o aumento de dose é local, da ordem de alguns micrômetros, dependendo do tamanho das nanopartículas e da energia do feixe primário. Para o feixe de 50 kVp, o DEF encontrado para uma incorporação heterogênea de seis aglomerados de AuNPs, correspondendo a um modelo clínico real, foi de 1,79, com incerteza de 0,4%. Com base nos resultados obtidos pode-se concluir que as energias de ortovoltagem proporcionam maior fator de aumento de dose que feixes de megavoltagem utilizados em teleterapia convencional. Além disso, o reforço local de dose pode proporcionar um fator de radiossensibilização celular se as AuNPs forem incorporadas no núcleo das células, nas redondezas do DNA, proporcionando um maior potencial de controle tumoral. / The incorporation of metal nanoparticles into tumor tissues has been studied in radiation therapy given of the dose enhancement that can be obtained in the target volume of the treatment. Studies indicate that gold nanoparticles (AuNP) are among the highest biologically viable for such applications, due to their low toxic potential. In addition, studies show that AuNP from a few nanometers to a few micrometers can permeate blood vessels that feed tumors, allowing their incorporation into tumor cells. Hence, this study´s goal was to study the dose enhancement factors obtained in radiation therapy with AuNP incorporated in the tumor using orthovoltage, brachytherapy and teletherapy beams. This work used a computational methodology, through Monte Carlo simulation with the PENELOPE package. Clinical beams of 50, 80, 150 and 250 kVp, Ir-192 and 6 MV were simulated with a tumor cell model with incorporated AuNPs. The cell model has maximum outer diameter of 13 m and 2 m of nucleus diameter. Two models of AuNP incorporation were implemented: homogeneous model and heterogeneous model. In the homogeneous model the AuNP were distributed homogeneously in the nucleus and the cells were irradiated in the different beams studied to evaluate the dose enhancement factors (DEF) as a function of concentration of gold in the cell and radiation beam. In the heterogeneous model, clusters of AuNPs were simulated individually within the cell. In this model, the radiation spectra used was selected among those that presented the best performances in the homogeneous model. The fluence of particles ejected from the AuNPs, the DEFs, the dose distributions and dose profiles for clusters of 50 to 220 nm in the cell were evaluated. The results obtained for the homogeneous model show that lower energy beams provide the highest DEFs for the same concentration of AuNP. The highest DEFs obtained were 2.80; 2.99; 1.62 and 1.61, for the beams of 50 kVp, 80 kVp, 150 kVp, 250 kVp, respectively, with a maximun uncertainty of 1.9% for the 250 kVp beam. Through the results obtained with the heterogeneous model it was possible to conclude that the electrons ejected from he AuNPs have the major influence on the local dose enhancement. The dose profiles extracted from the dose distributions for the simulated clusters allowed the evaluation of the ranges for the 50, 20 and 10% isodoses in the surroundings of the AuNPs. Through these dose profiles, it can be concluded that the dose increase is local, in the order of a few micrometers, depending on the size of the nanoparticles and the energy of the primary beam. For the 50 kVp beam, the DEF found for a heterogeneous incorporation of six clusters of AuNPs, corresponding to an actual clinical model, was 1.79, with uncertainty of 0.4%. Based on the results obtained it can be concluded that kilovoltage energies provide a higher dose enhancement factor than megavoltage beams used in teletherapy. In addition, local dose enhancement may provide a cellular radiosensitization factor if the nanoparticles are incorporated in the nucleus of the cells, in the vicinity of the DNA, providing an enhanced potential for tumor control.
65

Junções moleculares e agregados de nanobastões de ouro: um estudo SERS / Molecular junctions and gold nanorods aggregates: SERS study

Klester dos Santos Souza 26 February 2016 (has links)
A Espectroscopia Raman Intensificada pela Superfície (SERS) é um efeito de intensificação da intensidade Raman de uma molécula adsorvida numa superfície metálica nanoestruturada. Esta característica permite a utilização do SERS na caracterização vibracional de sistemas como junções moleculares (JM) (JM são sistemas constituídos de fios moleculares sintetizados em junções do tipo metal|fiomolecular|metal) e, no entendimento de quais características morfológicas de agregados metálicos mais influenciariam no sinal SERS obtido. Portanto, esta tese apresenta os seguintes objetivos: (a) síntese e caracterização de substratos SERS ativos, nanoesferas (AuNE) e nanobastões (AuNB) de ouro e eletrodo de ouro ativado eletroquimicamente; (b) síntese e caracterização SERS de fios moleculares em JM; (c) estudo do acoplamento plasmônico entre as superfícies metálicas em JM; (d) correlação entre SERS - morfologia de agregados individuais de AuNB. Os fios moleculares estudados foram os da família das oligofeniliminas (OPI) e, no melhor do nosso entendimento, esta foi a primeira vez que fios moleculares desta família foram caracterizados por Raman e SERS. As JM apresentaram um comportamento SERS não esperado. Enquanto para o modo vibracional, v(CS), a intensidade da banda se apresentou constante com o aumento do espaçamento entre as nanoestruturas metálicas (para distâncias de até 5 nm), o modo vibracional, β(CH), teve a intensidade de sua banda aumentada. Este comportamento foi explicado considerando a diferente natureza da interação dos plasmons nas JM, sendo estas interações do tipo, ressonância de plasmon de superfície (LSPR) - dipolo imagem, para ambos os modos. No entanto, para o modo β(CH) existe também uma intensificação extra devido ao aumento da polarizabilidade dos fios moleculares com o aumento do número de unidades. A correlação SERS - morfologia dos agregados de AuNB indicam que, para agregados onde predominam interações ponta a ponta, os espectros SERS apresentavam uma maior intensidade quando comparados com aqueles em que interações lado a lado predominavam. No entanto, este comportamento não foi observado para agregados contendo mais do que cinco nanopartículas onde estes dois tipos de interações ocorrem indicando que deve existir um acoplamento dos plasmons destes dois tipos de interações contribuindo para maiores valores de intensidade SERS. / Surface enhanced Raman Spectroscopy (SERS) is a Raman enhancing effect of molecules adsorbed on nanostructured metal surfaces. This characteristic allows the use of SERS in the vibrational study of Molecular Junction systems (MJ) (MJ is a system formed by Molecular Wires (pi-conjugated molecules) synthesized in metal junctions like metal|molecular-wire|metal). In addition, we can also use SERS to understand the influence of morphological characteristic of gold nanostructures. This thesis aims: (a) synthesis and characterization of gold nanospheres (AuNS), nanorods (AuNR) and gold electrode (electrochemically activated); (b) synthesis and vibrational studies of molecular wires in JM; (c) plasmon coupling studies between flat surface and gold nanorods; (d) correlation SERS - AuNR morphology of individual aggregates. For the best of our knowledge, this was the first time that oligophenilenelimine (OPI) as molecular wire was characterized by Raman and SERS. The MJ showed an unusual behavior such that the v(CS) vibrational mode remained constant in intensity with the increasing of the gap spacing (within 5 nm) while the β(CH) increased with the increase of the gap. This behaviour was related to the different nature of the interaction between plasmons resonances in JM (surface plasmon resonance (LSPR) - dipole image) for the first case and due to chemical contributions by the molecular wires for the second vibrational mode. The results for SERS - morphology AuNR aggregates correlation showed (for small aggregates) that when in the aggregate predominated end-by-end interaction SERS spectra showed a higher intensity when compared to those in which interactions side-by-side predominated. Although, this behavior was not observed for aggregates containing more than five nanoparticles indicating that there is not a preferential interaction between the nanorods for such aggregates and that a mixture of both will be preferable for large SERS intensities.
66

Carbon Nanotube- and Gold Nanoparticle-Based Materials For Electrochemical and Colorimetric Sensing Applications

Paudyal, Janak, 9255967 09 November 2016 (has links)
Carbon nanotubes (CNTs) and gold nanoparticles (AuNPs) are widely used for sensing applications due to their distinctive electrical and optical properties, and we have explored the development of methods that enable the incorporation of these nanomaterials into new and improved sensing devices. As a means for fabricating simple, low-cost and fast detection platforms for various applications, we have developed paper-based electrochemical detection platforms based on CNTs or platinum nanoparticle (PtNP)-CNT composite materials. We describe the use of a paper-based, low density, a three-dimensional thin film of interconnected CNTs as an electrode material. We studied the electrochemical properties of these paper-based CNT electrodes and demonstrated their use as an electrochemical sensor for the sensitive detection of guanine-based nucleotides. We further describe the functionalization of this paper-based electrode by fabricating a PtNP-SWCNT hybrid film via a vacuum filtration-based method. The interconnected PtNP structure formed on top of the CNT-coated paper was directly used as an electrocatalyst for methanol oxidation. Compared to paper-based PtNP-SWCNT hybrid films formed by electrochemical deposition, hybrid films formed by vacuum filtration showed a higher electrochemical surface area and enhanced electrocatalytic response to methanol oxidation. We have also developed methods based around DNA-modified AuNPs, which offer an excellent colorimetric platform for target detection. The DNA density on the surface of modified AuNPs affects enzymatic activity, colloidal stability of AuNPs, the orientation of the probe DNA and its hybridization efficiency. The combination of all these factors ultimately dictates the reaction time and sensitivity of colorimetric assays. We demonstrate the use of DTT as a modulator to control DNA surface coverage on the surface of AuNPs. Using this DTT treatment and a novel probe for exonuclease III activity, we have developed a colorimetric assay based on DTT-treated, DNA-modified AuNPs that can achieve more sensitive and rapid detection of DNA and enzymes relative to existing sensor platforms.
67

Colloidal self-assembly of anisotropic gold nanoparticles / Kolloidal självsammansättning av anisotropa guldnanopartiklar

Emilsson, Samuel January 2020 (has links)
The colloidal self-assembly of plasmonic gold nanoparticles (AuNPs) is of interest to utilize the plasmonic coupling effects that arise between nanoparticles. The enhanced properties of anisotropic AuNPs make them particularly attractive in self-assemblies. Herein, a literature study into the different strategies used to obtain self-assemblies of AuNPs using molecular linkers is presented. The use of nanospheres (AuNS) and nanorods (AuNRs) were mainly reviewed. Thereafter, two different nanobipyramids (AuBPs) were investigated for use in self-assemblies. The concentration of cetyltrimethylammonium bromide (CTAB), which coats the AuNP surface, was manipulated to study the stability of the AuNPs. A stable, meta-stable and non-stable region were identified for the nanoparticles. At low CTAB levels, the AuNPs preferentially assemble end-to-end. The addition of L-cysteine to stable AuNP dispersion induced end-to-end assembly, showing promise as a molecular linker for AuBPs. The addition of excess CTAB stabilized the assemblies over time. The kinetic behaviour of the two AuBPs differed, suggesting the effect of the AuNP shape on the self-assembly kinetics. This study provides a starting point for the development of a robust self-assembly strategy for anisotropic AuNPs by using L-cysteine as a molecular linker. / Den kolloidala självsammansättningen av ytplasmoniska guld nanopartiklar (AuNPs) är av intresse för att utnyttja de plasmoniska kopplingseffekterna som uppstår mellan nanopartiklar. De fördelaktiga egenskaperna hos anisotropa AuNP gör dem särskilt intressanta för självsammansättningar. En litteraturstudie har gjorts på de olika strategier som används för att erhålla självsammansättningar av AuNPs med hjälp av molekylära länkar. Användningen av nanosfärer (AuNS) och nanostavar (AuNRs) i självsammansättningar undesöktes huvudsakligen. Därefter undersöktes två olika nanobipyramider (AuBPs) för användning i självsammansättningar. Koncentrationen av cetyltrimetylammonium bromid (CTAB), som täcker AuNP-ytan, manipulerades för att undersöka AuNPs stabilitet. En stabil, meta-stabil och instabil region identifierades för nanopartiklarna. Vid låga CTAB-nivåer sammansätts AuNPs ände-mot-ände. Tillsatsen av L-cystein till stabila AuNP dispersioner inducerade sammansättningar ände-mot-ände, vilket visar L-cysteins potential som en molekylär länk för AuBPs. Tillsatsen av en stor mängd CTAB stabiliserade självsammansättningarna för en längre tid. Det kinetiska beteendet hos de två AuBPs skilde sig, vilket tyder på effekten av AuNP-formen på den självsammansättningskinetiken. Denna studie erbjuder en startpunkt för utvecklingen av en robust självsammansättningstrategi för anisotropa AuNPs genom att använda L-cystein som en molekylär länk.
68

Goldnanopartikel: Eine Plattform für multimodale Diagnostik und Therapie in der experimentellen Nuklearmedizin

Pretze, Marc 17 January 2024 (has links)
Es wurden Goldnanopartikel (AuNP) hergestellt, die eine einheitliche Größenverteilung von 3–5 nm aufweisen. Damit kann eine Mehrfachfunktionalisierung erreicht werden, d.h. gleich mehrere tumorspezifischen Moleküle an einen AuNP gekoppelt werden können und somit eine stark erhöhte Avidität zur Tumorzelle erzielt werden kann. Diese so hergestellten AuNP wurden mit diagnostisch oder therapeutisch wirksamen Radionukliden beladen bzw. radiomarkiert. Diese so funktionalisierten und radiomarkierten AuNP reicherten sich in Tumorgewebe an mit nur geringfügiger Akkumulation in gesundem Gewebe.:1. Einleitung 1 1.1 Radioaktive Arzneimittel zur Diagnostik und Therapie in der Nuklearmedizin 1 1.2 Radioaktives Gold gegen Krebs 2 1.3 Aktueller Stand der Forschung zu Goldnanopartikeln 3 1.4 Chemische Charakterisierung von oberflächen-modifizierten AuNP 5 1.5 Zielstellung 7 2. Ergebnisse 8 2.1 Gastrin-Releasing Peptide Receptor- and Prostate-Specific Membrane Antigen-Specific Ultrasmall Gold Nanoparticles for Characterization and Diagnosis of Prostate Carcinoma via Fluorescence Imaging 8 2.2 Targeted 64Cu-labeled gold nanoparticles for dual imaging with positron emission tomography and optical imaging 20 2.3 αvβ3-Specific gold nanoparticles for fluorescence imaging of tumor angiogenesis 34 2.4 68Ga-NeoB: Preclinical results on imaging of gastrointestinal stromal tumors and determination of target receptor density in the gastrointestinal tract 65 2.5 GMP-compliant production of [68Ga]Ga-NeoB for positron emission tomography imaging of patients with gastrointestinal stromal tumor 80 2.6 Ac-EAZY! Towards GMP-Compliant Module Syntheses of 225Ac-Labeled Peptides for Clinical Application 93 3. Diskussion 105 3.1 Entwicklung von klinisch anwendbaren radiomarkierten Goldnanopartikeln gegen Krebs 105 3.2 Klinische Translation von neuen diagnostischen und therapeutischen Radiopharmaka 106 4. Zusammenfassung und Ausblick 108 5. Literaturverzeichnis 110 Abkürzungsverzeichnis 115 Erklärungen und Versicherung 117 / Gold nanoparticles (AuNPs) with a uniform size distribution of 3-5 nm were produced. This allows multiple functionalization to be achieved, i.e. several tumour-specific molecules can be coupled to one AuNP at the same time and thus a greatly increased avidity to the tumour cell can be achieved. These AuNPs produced in this way were loaded or radiolabeled with diagnostically or therapeutically effective radionuclides. These functionalized and radiolabeled AuNPs accumulated in tumour tissue with only slight accumulation in healthy tissue.:1. Einleitung 1 1.1 Radioaktive Arzneimittel zur Diagnostik und Therapie in der Nuklearmedizin 1 1.2 Radioaktives Gold gegen Krebs 2 1.3 Aktueller Stand der Forschung zu Goldnanopartikeln 3 1.4 Chemische Charakterisierung von oberflächen-modifizierten AuNP 5 1.5 Zielstellung 7 2. Ergebnisse 8 2.1 Gastrin-Releasing Peptide Receptor- and Prostate-Specific Membrane Antigen-Specific Ultrasmall Gold Nanoparticles for Characterization and Diagnosis of Prostate Carcinoma via Fluorescence Imaging 8 2.2 Targeted 64Cu-labeled gold nanoparticles for dual imaging with positron emission tomography and optical imaging 20 2.3 αvβ3-Specific gold nanoparticles for fluorescence imaging of tumor angiogenesis 34 2.4 68Ga-NeoB: Preclinical results on imaging of gastrointestinal stromal tumors and determination of target receptor density in the gastrointestinal tract 65 2.5 GMP-compliant production of [68Ga]Ga-NeoB for positron emission tomography imaging of patients with gastrointestinal stromal tumor 80 2.6 Ac-EAZY! Towards GMP-Compliant Module Syntheses of 225Ac-Labeled Peptides for Clinical Application 93 3. Diskussion 105 3.1 Entwicklung von klinisch anwendbaren radiomarkierten Goldnanopartikeln gegen Krebs 105 3.2 Klinische Translation von neuen diagnostischen und therapeutischen Radiopharmaka 106 4. Zusammenfassung und Ausblick 108 5. Literaturverzeichnis 110 Abkürzungsverzeichnis 115 Erklärungen und Versicherung 117
69

Heat Transfer from Optically Excited Gold Nanostructures into Water, Sugar, and Salt Solutions

Green, Andrew J. January 2013 (has links)
No description available.
70

Kinetische Untersuchungen zur Reduktion von Nitroaromaten mit Goldnanopartikeln

Fenger, Robert 22 July 2013 (has links)
Goldnanopartikel werden in der kolloidalen Katalyse als Modellsystem genutzt, um den Einfluss des Partikelgröße, der Partikelform und der Zusammensetzung in bimetallischen Systemen sowie der Ligandensphäre auf die katalytische Reduktion von 4-Nitrophenol zu 4-Aminophenol zu untersuchen. Goldnanopartikel eignen sich vor allem deshalb als Modellsystem, da sie in kurzer Zeit, in hohen Ausbeuten und mit definierten Eigenschaften hergestellt werden können. Es konnte erstmals nachgewiesen werden, dass Goldnanopartikel mit einem Durchmesser von 13 nm die höchste katalytische Umsetzungsrate bei der Reduktion von 4-Nitrophenolzu 4-Aminophenol besitzen. Im Zuge dieser Arbeit wird dieses Aktivitätsmaximum der Nanopartikel näher untersucht. Dazu werden drei Aspekte vorgestellt: die Abhängigkeit von der Goldnanopartikelform, die Abhängigkeit der Substratgröße und der Einfluss der Ligandensphäre auf die Katalyse. Überraschenderweise ist CTAB als oberflächenaktiver Ligand ein Co-Katalysator bei der Reduktion, während die Anwesenheit von Natriumcitrat die Reaktion verlangsamt. Es wurden Aspekte wie die Konzentration und die Größe der Goldnanopartikel in dem komplexen Wechselspiel der Aktivitäten des Katalysators und Co-Katalysators untersucht. Dies führte zu der beispielgebenden Erkenntnis, dass oberflächenaktive Liganden mit positiver Ladung und Stickstofffunktionen die Katalyse positiv beeinflussen. In einer weiteren Studie wurde der Reaktionsmechanismus der 6-Elektronenreduktion von 4-Nitrophenol zu 4-Aminophenol erforscht. Es konnte zum ersten Mal gezeigt werden, dass die Reduktion in zwei Teilschritten abläuft. N-Arylhydroxylamin ist als wichtiges Intermediat in der Lösung der Reduktion erstmals nachgewiesen worden. Drei kinetische Regime werden für die Reduktion von 4-Nitrophenol gefunden und geben einen Einblick in die Oberflächenreaktion von Nitroaromaten an Goldnanopartikeln. / Gold nanoparticles as model systems in colloidal catalysis are used to gain insights into the decisive parameters of the catalytic model reduction. Size, shape, composition of bimetallic systems, and ligand sphere are factors influencing the reduction of 4-nitrophenol to 4-aminophenol by sodium borohydride in the presence of gold nanoparticles. The increasing interest in gold nanoparticle catalysis is mainly due to their stability, their fast and high yield synthesis as well as their extraordinary diversity of the modes of preparation. This thesis is assigned to unravel the important parameters of gold nanoparticle catalysis. In the first part of the thesis, CTAB-stabilized gold nanoparticles were synthesized by applying the seeding-growth approach in order to gain information about the size dependence of the catalytic reduction of 4-nitrophenol to 4-aminophenol with sodium borohydride. Unexpectedly, CTAB-stabilized gold nanoparticles with a diameter of 13nm were most efficient in this complex system. In this context, molecular aspects such as shape, size of the substrate and ligand sphere were discussed as possible reasons for the enhanced activity for medium sized gold nanoparticles. Here, it was shown for the first time that the ligand sphere plays a crucial role in colloidal catalysis. Micellar catalysis with colloidal gold nanoparticles was performed by means of ligand exchange procedures. In addition, this thesis shows for the first time that intermediates can be unambiguously identified in the reaction solution with colloidal gold nanoparticles as catalysts. 4-N-hydroxylaminophenol was found to be the key intermediate in this system. In this context, three kinetic regimes which were crucial for the aromatic nitro reduction are found to cover the reaction kinetics. Thus, this thesis provides new insight into the catalytic process itself and leads to a better understanding of the catalytic activity of gold nanoparticles.

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