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Charakterizace polovodičových nanovláken / Characterization of semiconducting nanowiresNovotný, Karel January 2015 (has links)
This diploma thesis is focused on characterization of semiconductive nanowires. Theoretical part of thesis deals with basic physical properties of TiO2 and a search of selected properties of titanium dioxide nanostructures is preseted. The experimental part describes several spectroscopic measurements carried out with complex of TiO2 nanowires. The influence of gold nanoparticles (deposited on the nanowire surface) on sample properties is also tested. The final part of thesis is devoted to methodology for measurement of electrical properties. These experiments are carried out only with one nanowire. Focused electron beam induced deposition (resp. Focused ion beam induced deposition) and electron lithography are utilized.
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Funkční nanočástice pro plasmonické biosenzory / Functional nanoparticles for plasmonic biosensorsPřítulová, Marie January 2016 (has links)
This thesis aims to prepare functional gold nanoparticles (AuNPs) and use them in conjunction with a surface plasmon resonance (SPR) biosensor for highly sensitive detection of carcinoembryonic antigen (CEA). In this work, preparation of colloidal AuNPs was investigated and a three-step synthesis was optimized to yield spherical nanoparticles with a diameter of about 100 nm and smooth surface. The synthesized AuNPs were functionalized by a self-assembled monolayer of carboxy-PEG alkanethiols and streptavidin and characterized by UV/VIS spectroscopy and -potential method. Finally, the functionalized AuNPs were employed in sandwich assay for the sensitive detection of CEA and it was demonstrated that they can enhance sensor response to CEA by a factor of 100 compared to the direct detection of CEA.
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Příprava zlatých nanočástic ve vodných a organických prostředích laserovou ablací femtosekundovými pulsy, jejich charakterizace a aplikace / Preparation of gold nanoparticles in aqueous and organic media by femtosecond laser ablation, their characterization and applicationHochmann, Lukáš January 2016 (has links)
No description available.
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Screening of Selected Libyan Medicinal Plants for the Synthesis of Metal Nanoparticles and their activity against Streptococcus mutansAlshibani, Salah Ramadan January 2020 (has links)
>Magister Scientiae - MSc / Nanotechnology has emerged as an elementary division of modern science and stemmed directly from green chemistry twelve basic concepts, it receives global attention due to its unique character and ample applications. It also has great potential to mitigate the challenges they face in various fields, especially medical sector. Nanodrugs are increasingly considered as a potential candidate to carry therapeutic agents safely into a targeted compartment in an organ, particular tissue or cell. In this study, twenty (20) Libyan plants were selected and evaluated for their potential to synthesis gold and silver nanoparticles. The screening of the different plant extracts was performed using 96 well plate method at 25 °C and 70 °C. The NPs formation was confirmed and characterized using UV- Vis, DLS, HR-TEM and EDX. A well-defined NPs were obtained at high temperature (70 °C). The Au NPs had an average diameter of 92 nm at 25 °C and 66 nm at 70 °C. The zeta potential values were observed to be negative (-14 to -24) and indicate the stability of the Au NPs. The HR-TEM showed polydispersity, which decreased at higher temperature (70 °C). The stability of Au NPs in nutrient broth prior was conducted as well. All the Au NPs under study showed stability, only minimal changes in the UV-Vis spectra can be observed. Two plant extract viz Pistacia atlantica, Junipers phoenicea showed consistent results and forming stable and smaller NPs compared to others, both of the plant extracts and the corresponding NPs were tested against Streptococcus mutans and showed MIC value ~ 49 g/mL. In case of silver NPs, two plant extracts viz J. phoenicea, Rosmarinus officinalis, showed superior results than the others; both plants produced stable and small Ag NPs. The antibacterial activity against S. mutans demonstrated MIC valus ~ 50 g/mL. The synthesised NPs showed a promising bioactivity for developments of new antibacterial agents against S. mutans strains. Dose-dependent activity was observed for the tested NPs.
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In vitro Interaction of Nanoparticles with Mitochondria for Surface Enhanced Raman Spectroscopy and Cell ImagingMkandawire, Msaukiranji 15 October 2010 (has links)
Mitochondria are an attractive target for the design of cancer therapy. One of the mechanisms by which chemotherapeutics destroy cancer cells is by inducing apoptosis through extrinsic or intrinsic apoptotic pathways. Extrinsic pathways target cell surface receptors whilst intrinsic pathways target mitochondria. Several studies have shown cancer cell destruction through the extrinsic pathways, which target cancer-specific overexpressed growth factor receptors on the cell membrane. Although the mitochondria dependent apoptotic process is well understood, its application in cancer therapy is still not well developed. Therefore, to design an effective cancer therapy targeting mitochondria, a good understanding in mitochondria dependent apoptotic process is required. Recent developments in nanotechnology have enabled live cell investigations and non-destructive methods to obtain cellular information. The availability of such information would assist to design methods of targeted apoptosis induction.
In view of this, I report on studies towards development of cancer therapy where nanoparticles (NPs) were targeted to human cell mitochondria for two purposes: (a) development of cell-imaging tools to investigate the fundamental cell biological pathways inside cells and (b) induction of apoptosis by targeting nanoparticles to mitochondria. Current medical and biological fluorescent imaging methods are mainly based on dye markers, which are limited in light emission per molecule, as well as photostability. Consequently, NPs are gaining prominence for molecular imaging because of their strong and stable fluorescence.
Additionally, in order to get insight of mitochondrial molecular information, I investigated the use of optical properties of gold nanoparticles (Au NPs) for surface enhanced Raman spectroscopy (SERS). In this study, two types of Au NPs - nanospheres (Au NS) and nanorods (Au NR) were investigated. Results from this study showed the enhancement effect of Au NPs in Raman spectra of mitochondria, especially in the region from 1500 to 1600 cm-1. In this region, normal Raman spectra of mitochondria showed the presence of some understated Raman peaks probably due to the excitation wavelength dependence. Au NRs showed a larger enhancement effect than Au NS with respect to the penetration depth of the plasmonic nearfield enhancement effect. Although, the details of the enhancement mechanism are beyond the current studies, Au NPs could be enhancing vibrations of aromatic residues in proteins. This study therefore showed that Au NPs could enhance Raman spectra of mitochondria and in addition the shape of the nanoparticles had a significant effect on SERS spectra.
In living cells, I investigated some transfection methods and targeting of NPs to mitochondria or cytosolic actin subunits. I tested the performance of three transfection reagents to deliver nanodiamonds (NDs) into living cells. Antibody functionalized NDs were targeted to mitochondria or cytosolic actin subunits. Three transfection reagents were used: cationic liposomes PULSin™, the cell penetrating peptide protamine, and oligosaccharide modified polypropylene imine (PPI) dendrimers. Fluorescence imaging results revealed that dendrimers were the most efficient in delivering ND conjugates to targeted organelles. Protamine-mediated transfections appeared to target ND conjugates to intended organelles, although there was a tendency of unfunctionalized NDs to be directed to the nucleus. PULSin™-mediated transfection formed ND aggregates regardless of the functionalization moiety. This reflected the unsuitability of the cationic liposome to mediate ND transfections.
Further, I investigated the potential use of Au NPs for cell imaging and photothermal lysis of mitochondria inside cells. Just as above, I also tested the performance of the three-transfection reagents mentioned above on transfection capacity of Au NPs into living cells. Using transmission electron microscopy (TEM), oligosaccharide modified dendrimers showed the best transfection of functionalized Au NPs. Further experiments explored the use of the nearfield enhancement effect of Au NPs in combination with low-level laser irradiation (LLLI) to induce apoptosis in living cells. Analysis of the apoptotic process using cytochrome c release showed that Au NPs induced apoptosis most probably through mechanical disruption of the outer mitochondrial membrane. However, apoptosis was significantly accelerated in cells with mitochondrially targeted Au NRs than in cells without Au NRs. This study showed successful targeting of Au NPs to mitochondria in living cells, and demonstrated the potential of using Au NPs in combination with laser irradiation to induce the mitochondria dependent apoptotic pathway.
In conclusion, the potential use of Au NPs in SERS of mitochondria and the application of NDs for cell imaging of intracellular organelles were demonstrated. Lastly, Au NPs were targeted to mitochondria in living cells and could induce apoptosis due to mechanical disruption of the outer mitochondrial membrane. Consequently, application of low-level laser irradiation to Au NP transfected cells accelerated the apoptotic process.
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Towards stimuli-responsive functional nanocomposites: Smart tunable plasmonic nanostructures au-v02Kama Kama, Jean Bosco January 2010 (has links)
Magister Philosophiae - MPhil / The fascinating optical properties of metallic nanostructures, dominated by collective
oscillations of free electrons known as plasmons, open new opportunities for the
development of devices fabrication based on noble metal nanoparticle composite
materials. This thesis demonstrates a low-cost and versatile technique to produce
stimuli-responsive ultrafast plasmonic nanostructures with reversible tunable optical
properties. Albeit challenging, further control using thermal external stimuli to tune the
local environment of gold nanoparticles embedded in V02 host matrix would be ideal
for the design of responsive functional nanocomposites. We prepared Au-V02
nanocomposite thin films by the inverted cylindrical reactive magnetron sputtering
(ICMS) known as hollow cathode magnetron sputtering for the first time and report the
reversible tuning of surface plasmon resonance of Au nanoparticles by only adjusting
the external temperature stimuli. The structural, morphological, interfacial analysis and
optical properties of the optimized nanostructures have been studied. ICMS has been
attracting much attention for its enclosed geometry and its ability to deposit on large
area, uniform coating of smart nanocomposites at high deposition rate. Before
achieving the aforementioned goals, a systematic study and optimization process of
V02 host matrix has been done by studying the influence of deposition parameters on
the structural, morphological and optical switching properties of V02 thin films. A
reversible thermal tunability of the optical/dielectric constants of V02 thin films by
spectroscopic ellipsometry has been intensively also studied in order to bring more
insights about the shift of the plasmon of gold nanoparticles imbedded in V02 host
matrix.
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Contrast agent imaging using an optimized table-top x-ray fluorescence and photon-counting computed tomography imaging systemDunning, Chelsea Amanda Saffron 04 November 2020 (has links)
Contrast agents are often crucial in medical imaging for disease diagnosis. Novel
contrast agents, such as gold nanoparticles (AuNPs) and lanthanides, are being ex-
plored for a variety of clinical applications. Preclinical testing of these contrast agents
is necessary before being approved for use in humans, which requires the use of small
animal imaging techniques. Small animal imaging demands the detection of these contrast agents in trace amounts at acceptable imaging time and radiation dose. Two
such imaging techniques include x-ray fluorescence computed tomography (XFCT)
and photon-counting CT (PCCT). XFCT combines the principles of CT with x-ray
fluorescence by detecting fluorescent x-rays from contrast agents at various projections to reconstruct contrast agent maps. XFCT can image trace amounts of AuNPs
but is limited to small animal imaging due to fluorescent x-ray attenuation and scatter. PCCT uses photon-counting detectors that separate the CT data into energy
bins. This enables contrast agent detection by recognizing the energy dependence of
x-ray attenuation in different materials, independent of AuNP depth, and can provide
anatomical information that XFCT cannot. To achieve the best of both worlds, we
modeled and built a table-top x-ray imaging system capable of simultaneous XFCT
and PCCT imaging.
We used Monte Carlo simulation software for the following work in XFCT imaging of AuNPs. We simulated XFCT induced by x-ray, electron, and proton beams
scanning a small animal-sized object (phantom) containing AuNPs with Monte Carlo
techniques. XFCT induced by x-rays resulted in the best image quality of AuNPs,
however high-energy electron and medium-energy proton XFCT may be feasible for
on-board x-ray fluorescence techniques during radiation therapy. We then simulated
a scan of a phantom containing AuNPs on a table-top system to optimize the detector
arrangement, size, and data acquisition strategy based on the resulting XFCT image
quality and available detector equipment. To enable faster XFCT data acquisition,
we separately simulated another AuNP phantom and determined the best collimator
geometry for Au fluorescent x-ray detection.
We also performed experiments on our table-top x-ray imaging system in the lab.
Phantoms containing multiples of three lanthanide contrast agents were scanned on
our tabletop x-ray imaging system using a photon-counting detector capable of sustaining high x-ray fluxes that enabled PCCT. We used a novel subtraction algorithm
for reconstructing separate contrast agent maps; all lanthanides were distinct at low
concentrations including gadolinium and holmium that are close in atomic number.
Finally, we performed the first simultaneous XFCT and PCCT scan of a phantom
and mice containing both gadolinium and gold based on the optimized parameters
from our simulations.
This dissertation outlines the development of our tabletop x-ray imaging system
and the optimization of the complex parameters necessary to obtain XFCT and PCCT
images of multiple contrast agents at biologically-relevant concentrations. / Graduate
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Synthèse et caractérisation de nanocomposites conducteurs à base de « graphène » et de polysaccharides / Synthesis and characterization of conducting nanocomposites based « graphene » and polysaccharidesDhahri, Abdelwaheb 20 April 2017 (has links)
L'objectif principal de cette thèse a été d'expérimenter de nouvelles voies d'exfoliation des feuillets de graphène dans des matrices polysaccharides telles que la cellulose et le chitosane dopé avec des nanoparticules d'or (Au). Notre stratégie a été d'explorer de nouvelles voies de greffage de molécules et de macromolécules sur des feuillets d'oxyde de graphène (GO). Dans un premier temps, nous avons donc oxydé un graphite commercial par la méthode de Hummers qui est apriori la méthode la plus simple à mettre en oeuvre pour produire une suspension stable de feuillets d'oxyde de graphène totalement exfoliés dans l'eau. L'intérêt de cette oxydation est l'obtention de fonctions acide carboxylique et époxyde susceptibles d'être fonctionnalisées en deux étapes par l'éthylénediamine puis par un polysaccharide tel que la cellulose. En effet, afin d'améliorer la compatibilité du graphite oxydé avec des matrices organiques telle que la cellulose, l'idée est de lui greffer des chaînes polysaccharides. Ces résultats ont permis de mettre en évidence l'exfoliation partielle des feuillets de graphène après fonctionnalisation et l'obtention d'un taux de greffage massique d'environ 35% pour la cellulose. La conductivité électrique des nano-composites correspondants a aussi été étudiée par des mesures diélectriques à des températures variées. L'augmentation de la conductivité électrique après la fonctionnalisation du graphite oxydé a mis en évidence une solvo-thermoréduction simultanément à la fonctionnalisation. Enfin, le dopage de ce matériau par des particules d'or a permis d'obtenir une conductivité électrique de 1.60 10-4 S m-1. En ce qui concerne le matériau composite à base de chitosane, la démarche scientifique a été la même que pour l'analogue cellulose, le taux de greffage massique a été d'environ 68% et nous avons en plus testé son activité catalytique vis-à-vis de la conversion du 4-Nitrophénol en 4-Aminophénol et les résultats obtenus ont été très satisfaisants / The main objective of this thesis has been to experiment a new ways of exfoliation of graphene sheets in polysaccharide matrices such as cellulose and chitosan doped with gold nanoparticles (Au). Our strategy was to explore new routes for the grafting of molecules and macromolecules onto graphene oxide (GO). First, we have oxidized commercial graphite by the method of Hummers which is a priori the simplest method to implement to produce a stable suspension of graphene oxide sheets totally exfoliated in water. The advantage of this oxidation is the formation of carboxylic acid and epoxy functional groups onto the graphite surface that can be functionalized in two stages by ethylenediamine and then by a polysaccharide such as cellulose. Indeed, in order to improve the compatibility of graphite oxide with organic matrix such as cellulose, the idea is to graft it onto polysaccharide chains. These results made it possible to demonstrate the partial exfoliation of the graphene sheets after functionalization and to obtain a percentage of grafting of about 35wt% for cellulose. The electrical conductivity of the corresponding nanocomposites has also been studied by dielectric measurements at various temperatures. The increase of the electrical conductivity after the functionalization of graphite oxide showed a solvo-thermo reduction simultaneously with the functionalization. Finally, the doping of this material by gold particles made it possible to obtain an electrical conductivity of 1.60 10-4 S m-1. Concerning chitosan-based composite materials, the scientific approach was the same as cellulose substrate and we obtained a percentage of grafting of 68wt%. In addition, its catalytic activity for the conversion of 4-Nitrophenol to 4-Aminophenol was of high efficiency
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Synthèses, analyses et applications de systèmes à base de nanoparticules hybrides Or/Thiol / Synthesis, analysis and application based systems hybrid nanoparticles Metal/OrganicBouyon Yenda, Tracy Christ 16 December 2016 (has links)
Cette thèse développe la synthèse contrôlée et la purification de nanoparticules d’or hybrides, AuNPs stabilisées par des thiols organiques modulant leurs propriétés de surface. Les applications visent la catalyse et le domaine biomédical, impliquant un contrôle poussé des nanoobjets introduits. Les synthèses des AuNPs organiques sont développées à partir de la méthode de Brust, avec le 4-hydroxythiophénol et le 4-méthylthiophénol. Elles conduisent à des nanoparticules hybrides stables d’environ 2 nm. Les fractions de purifications sont analysées par MET, UV-visible, RMN et ATG, caractérisant le cœur d’or, la couche de ligands et leurs interactions. Il apparaît que les AuNPs hybrides présentent un assemblage de thiols en monocouche ou en multicouche. Une nouvelle voie de synthèse directe en phase aqueuse d’AuNPs d’environ 4 nm, stabilisées par le 4-hydroxythiophénol, est ensuite développée. Ces AuNPs sont purifiées par dialyse et caractérisées par MET, UV-visible, RMN et ATG. Les fractions d’AuNPs organiques, présentant différents états de surface, sont imprégnées dans la silice mésoporeuse SBA-15. Les isothermes d’adsorption et la manométrie sous diazote indiquent une bonne dispersion des AuNPs et une insertion dans les canaux. Nous introduisons l’exploration d’applications ciblées. L’utilisation des AuNPs organiques lors de l'oxydation d’alcènes tend à améliorer la sélectivité du sel de manganèse catalytique. Pour le domaine biomédical, les AuNPs aqueuses présentent une bonne dispersibilité en milieux aqueux biocompatibles. Les premiers tests in-vitro sur des cellules de sarcomes humains montrent une faible cytotoxicité et une bonne pénétration intracellulaire. / This Ph.D. work developed the controlled synthesis and purification of hybrid gold nanoparticles AuNPs, stabilized by organic thiols that are tuning their surface properties. The targeted applications are the catalysis and in the biomedical field, requiring a thorough control of the introduced nanoobjects. Syntheses of the organic AuNPs were developed from the Brust method, using 4-hydroxymercaptophenol or 4-methylmercaptophenol, leading to stable hybrid gold nanoparticles of size 2 nm. Purified fractions were characterized using TEM, UV-visible, NMR and TG analysis, issuing key data about the gold core, the organic layer and their interactions. Among the different fractions of AuNPs, the organic thiol ligands appeared to be assembled either as a monolayer or a multilayer pattern. A new direct route for synthesis of aqueous AuNPs of size 4 nm, stabilized by 4-hydroxymercaptophenol, has been developed. The AuNPs were purified using dialysis and characterized by TEM, UV-visible, NMR and TG analysis. Organic AuNPs, exhibiting different surface properties, were impregnated into SBA-15 mesoporous silica. Adsorption isotherms and nitrogen adsorption/desorption studies were in good agreement with the homogeneous distribution of AuNPs and the significant incorporation into the porosity. Finally, exploration of the targeted applications was started. The use of organic AuNPs for alkene oxidation tends to improve the selectivity of manganese salt catalyst. In the biomedical field, the aqueous AuNPs exhibited good dispersibility into biocompatible aqueous solvents. First in-vitro assays involving human sarcoma cells line showed limited cytotoxicity and good cellular uptake.
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Probing Nanoscale Electrochemical Processes on Single Gold Nanoparticles using Optical MicroscopyMolina, Natalia Y., 0000-0001-9555-2761 January 2022 (has links)
In this work, we use optical techniques to provide insight into how various components within electrochemical cells can impart apparent heterogeneity to single gold nanoparticle electrodes. Optical methods are advantageous in comparison to traditional electrochemical techniques due to their high sensitivity and spatial resolution, allowing us to study the impact of heterogeneity with single nanoparticle and single molecule sensitivity. Throughout the course of this dissertation, two optical techniques are discussed in detail, dark-field microscopy, and single molecule fluorescence imaging. We first began by studying the impact of the substrate using dark-field microscopy to monitor the electrodissolution kinetics of gold nanoparticles on thin films of tin-doped indium oxide (ITO), which is a commonly used supporting electrode for correlated optical and electrochemical studies. We found that ITO from two different suppliers showed marked differences in the gold electrodissolution kinetics, with ITO from one of the suppliers even showing poor sample-to-sample reproducibility across substrates within the same lot number. These results showed that the supporting electrode cannot be ignored when performing single nanoparticle structure-function studies. In the second work, we analyzed the electrodissolution of gold nanoparticles on well-behaved ITO substrates to investigate heterogeneity in their electrodissolution kinetics. The rate constants associated with the electrodissolution of Au NPs were extracted by fitting the intensity-time traces to a first-order kinetic model. We found that a non-negligible population of Au NPs didn’t fit the predictive kinetics model leading us to further probe whether surface effects play a role in the electrodissolution process. Super-localization imaging was used to track the center position of the Au NPs as they electrodissolved revealing three distinct electrodissolution behaviors, and a mechanism for the electrodissolution of Au NPs was proposed. Furthermore, calcite-assisted localization and kinetics (CLocK) microscopy was used to visualize changes in anisotropy and provide information as to how the shape of the Au NP changes as it electrodissolves. Lastly, in our third work, we provide insight as to how heterogeneity from all the different components of a single nanoparticle electrochemical sample impacts the apparent electrode performance. We proposed dark-field microscopy and single molecule fluorescence imaging as tools capable of detangling these effects. Moreover, we established Cresyl Violet as a reporter of single molecule electrochemistry and developed a two-working electrode optical system capable of visualizing single molecule activity. Lastly, we explored the relationships between Au NP size, Cresyl Violet activity and Au NP electrodissolution and found no clear trend between them suggesting the need for more studies to deconvolute these effects and provide meaningful insight into the structure-property relationships. Overall, this dissertation highlights the complexity of single nanoparticle studies and how heterogeneity can be induced from all the components of an electrochemical cell. / Chemistry
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