A study into the anti-inflammatory effects of silver nanoparticles andtheir potential clinical application

Cheung, Oi-fung, Stephanie., 張靄楓.

January 2008

published_or_final_version / Surgery / Master / Master of Philosophy

Nanoparticles.

Silver.

Inflammation - Animal models.

Cytokines.

Synthesis and characterization of nanostructured palladium-based alloy electrocatalysts

Sarkar, Arindam

22 October 2009

Low temperature fuel cells like proton exchange membrane fuel cells (PEMFC) are expected to play a crucial role in the future hydrogen economy, especially for transportation applications. These electrochemical devices offer significantly higher efficiency compared to conventional heat engines. However, use of exotic and expensive platinum as the electrocatalyst poses serious problems for commercial viability. In this regard, there is an urgent need to develop low-platinum or non-platinum electrocatalysts with electrocatalytic activity for the oxygen reduction reaction (ORR) superior or comparable to that of platinum. This dissertation first investigates non-platinum, palladium-based alloy electrocatalysts for ORR. Particularly, Pd-M (M = Mo and W) alloys are synthesized by a novel thermal decomposition of organo-metallic precursors. The carbon-supported Pd-M (M = Mo, W) electrocatalyts are then heat treated up to 900 oC in H2 atmosphere and investigated for their phase behavior. Cyclic voltammetry (CV) and rotating disk electrode (RDE) measurements reveal that the alloying of Pd with Mo or W significantly enhances the catalytic activity for ORR as well as the stability (durability) of the electrocatalysts. Additionally, both the alloy systems exhibit high tolerance to methanol, which is particularly advantageous for direct methanol fuel cells (DMFC). The dissertation then focuses on one-pot synthesis of carbon-supported multi-metallic Pt-Pd-Co nanoalloys by a rapid microwave-assisted solvothermal (MW-ST) method. The multi-metallic alloy compositions synthesized by the MW-ST method show much higher catalytic activity for ORR compared to their counterparts synthesized by the conventional borohydride reduction method. Additionally, a series of Pt encapsulated Pd-Co nanoparticle electrocatalysts are synthesized by the MW-ST method and characterized to understand their phase behavior, surface composition, and electrocatalytic activity for ORR. Finally, the dissertation focuses on carbon-supported binary Pt@Cu and ternary PtxPd1-x@Cu “core-shell” nanoparticles synthesized by a novel galvanic displacement of Cu by Pt4+ and Pd2+ at ambient conditions. Structural characterizations suggest that the Pt@Cu nanoparticles have a Pt-Cu alloy layer sandwiched between a copper core and a Pt shell. The electrochemical data clearly point to an enhancement in the activity for ORR for the Pt@Cu “core-shell” nanoparticle electrocatalysts compared to the commercial Pt electrocatalyst, both on per unit mass of Pt and per unit active surface area basis. The increase in activity for ORR is ascribed to electronic modification of the outer Pt shell by the Pt-Cu alloy core. However, incorporation of Pd to obtain PtxPd1-x@Cu deteriorates the activity for ORR. / text

Electrocatalysts

Palladium-based alloy

Synthesized nanoparticles

Nanoparticles in mesoporous materials : optical and electrochemical properties for energy storage applications

Patel, Mehul Naginbhai

22 October 2009

The design of nanoparticles in mesoporous supports is explored through synthetic strategies of electrophoretic deposition and electroless deposition with application towards energy storage. Electrophoretic deposition of nanoparticles into a mesoporous thin film is examined using charged nanocrystals in a low-permittivity solvent. To provide a basis for the deposition, the mechanism of particle charging in a low-permittivity solvent was studied. Dispersions of carbon black particles in toluene with an anionic surfactant were characterized using differential-phase optical coherence tomography with close electrode spacing to measure the electrophoretic mobility. The particle charge in concentrated dispersions was found to decrease as a function of increasing surfactant concentration. Partitioning of cations between the surfactant-laden particle surface and micelle cores in the double-layer was found to govern the dynamics of particle charging. Subsequently, charged Au nanocrystals were deposited by electrophoresis within perpendicular mesochannels of a TiO2 support. High loadings of 21 wt% Au with good dispersion were achieved within the mesoporous TiO2 support using electrophoretic deposition, which would otherwise be inhibited by the weak nanocrystal-support interaction. According to a modified Fokker-Planck equation, the mean penetration depth of a single nanocrystal inside of the perpendicular pores was found to be dependent on the electric field strength, electrophoretic mobility, pore diameter, nanocrystal size, and local deposition rate constant. Nanocomposites for electrochemical capacitors were designed via electroless deposition of redox-active MnO2 in a high surface area mesoporous carbon support. Disordered mesoporous carbon supports with a pore size of ~8 nm were used both in amorphous (AMC) and graphitic (GMC) form, with a ~1000-fold larger conductivity for GMC. High loadings of 30 wt% MnO2 were achieved in the AMC in the form of ~1 nm thick domains, which were highly dispersed throughout the support. Oxidation of the GMC was necessary to facilitate wetting and deposition of the MnO2 precursor in order to achieve high loadings of 35 wt% MnO2 with ~1 nm thickness. High gravimetric MnO2 pseudocapacitances of >500 F/gMnO2 were achieved at low loadings and low scan rate of 2 mV/s for both carbon supports. However, at high scan rates ≥100 mV/s, the MnO2 pseudocapacitance is twofold larger for MnO2/GMC, relative to MnO2/AMC. Sodium ion diffusion throughout both MnO2/AMC and MnO2/GMC was shown to be facile. For the GMC versus AMC support, the higher MnO2 pseudocapacitance is attributed to the higher electronic conductivity, which facilitates electron transport to the MnO2 domains. / text

Nanoparticles

Mesoporous materials

Electrophoretic deposition

Energy storage

Colloidal nanoparticles : a new class of laser gain media

Morgan, Robert Douglas

20 August 2010

Development of high average power lasers has historically been limited by the properties of available gain media. As a result it is either too costly or impractical to employ lasers in many applications for which they would otherwise be well suited. We have synthesized a new type of colloidal laser gain material that should possess many of the advantages of solid state media without their primary disadvantage: poor thermal performance. The colloid consisted of an emulsion of 20% Nd+3 doped phosphate glass nanoparticles suspended in nonanoic acid. The spectroscopic properties of the material were found to be consistent with those of bulk Nd+3 doped materials and suitable for laser development. / text

High average power lasers

Lasers

Nanoparticles

Surface design and controlled assembly of gold nanoparticles into biodegradable nanoclusters for biomedical imaging applications

Murthy, Avinash Krishna

15 October 2014

Gold nanoparticles have received significant interest recently due to their utility in biomedical imaging and therapy. Nanoparticles which exhibit intense extinction in the near infrared (NIR) region, where blood and tissue absorb light weakly, are of great interest as contrast agents for biomedical imaging applications. While strong NIR extinction often requires sizes greater than ~20-30 nm, effective clearance from the body to avoid toxic accumulation necessitates sizes below ~6 nm. Moreover, effective clearance depends upon lack of adsorption of serum proteins in the bloodstream onto the particles. Herein, this conflict is addressed by assembling sub-5 nm gold nanoparticles into clusters with controlled size and morphology, in order to provide intense NIR extinction. Furthermore, the surfaces of the primary gold nanoparticles are designed such that the particles avoid the adsorption of any serum proteins. Binary ligand monolayers of anionic citrate and appropriate amounts of either cationic lysine or zwitterionic cysteine are synthesized to completely prevent serum protein adsorption from undiluted fetal bovine serum. A mechanism is proposed whereby the zwitterionic tips which are present on both the lysine and cysteine ligands limit the interactions between serum proteins and the "buried" charges on the nanoparticle surfaces. These primary nanoparticles are subsequently assembled into biodegradable nanoclusters via "quenched assembly", wherein nanoclusters are assembled and subsequently quenched by the adsorption of a biodegradable polymer on the cluster surface. The sizes of completely reversible "quenched equilibrium" nanoclusters formed from gold nanoparticles coated with a mixture of lysine and citrate are tuned from 20 nm to 40 nm, and nanocluster size is semi-quantitatively predicted by a free-energy model. Additional control over nanocluster size and extinction is demonstrated by adding NaCl, which is shown to decrease the polymer adsorption on the clusters and thus decrease polymer bridging interactions. This nanocluster formation platform is extended to nanospheres capped with citrate and the thiolated, zwitterionic cysteine ligand. A general paradigm is presented whereby the sizes and optical properties of biodegradable gold nanoclusters formed from nanospheres which do not adsorb any serum proteins are tuned via control over van der Waals, electrostatic, depletion, and polymer bridging colloidal interactions. / text

Nanoparticles

Colloidal assembly

Protein adsorption

Biodegradable

Assembly of organic layers onto carbon surfaces

Tan, Emelyn Sue Qing

January 2006

This thesis presents the study of organic layers covalently assembled onto carbon surfaces. As a result of their attachment, the properties of carbon surfaces were controllably adjusted so that these surfaces could be used for desired applications. In order that a wide range of properties were imparted onto the carbon surface, many different modifiers were attached and thoroughly characterised. Three applications that the modified carbon surfaces were used for were the subsequent coupling of molecular species, adsorption of protein and assembly of aldehyde/sulfate-functionalised polystyrene (PS) and citrate-capped gold nanoparticles (NPs). Finally, patterning of different organic layers at pre-determined spatially defined locations on the one carbon surface was also investigated. The carbon surfaces used in this work were glassy carbon (GC) and pyrolysed photoresist film (PPF) surfaces. For PPF, methods for the reproducible fabrication of electrochemically suitable surfaces were investigated. The properties of GC and PPF surfaces are very similar apart from the surface roughness. PPF has near atomic smoothness and has RMS roughness values that are approximately four times smaller than GC. The first series of modifier layers attached to the carbon surfaces was via the oxidation of seven different primary amines. The different layers allowed the modulation of the wettability of the surface. Both n-tridecylamine (TDA, monoamine) and 1,12-diaminododecane (DAD, diamine) are able to form multilayers. The stability of TDA and DAD layers were tested by scanning, soaking and sonicating the layers in different media. Changes in the layer were monitored by the probe response of ferrocene monocarboxylic acid (FCA). However, atomic force microscope (AFM) depth profiling experiments showed that changes in the probe response did not indicate cleavage of the covalently attached layer and mechanisms are proposed to account for the changes in the response of the probe. Surface concentrations of the amine modifiers were estimated by the coupling of an electrochemically active species, FCA and nitrobenzoyl chloride (NBC). The electrochemical reduction of the 4-nitrophenylethylamine (NPEA) layer in acid caused the layer to 'shrink'. Surface concentration estimates of NPEA from acid reduction of layers with different thicknesses suggested that only a limited fraction of the p-nitrophenyl groups were reduced in acid. However, in ACN (acetonitrile)/0.1 M [Bu4N]BF4 (tetrabutyl ammonium fluoroborate) the relationship between the concentration of electroactive surface groups and layer thickness was linear. The other series of modifiers that was attached to alter the surface properties was performed by the reduction of aryl diazonium salts. Subsequent coupling reactions of tetraethylene glycol diamine (TGD) to para methylene carboxylic acid phenyl (MCA) and NBC to electrochemically reduced para nitro phenyl (NPh) layers were carried out. Surface concentrations of NPh as estimated from reduction scans was higher when reduction was performed in ethanol/water compared to acid. Four peaks at N1s binding energies were observed in x-ray photoelectron spectroscopy (XPS) spectra for both acid and ethanol/water reduced layers. The ability of attached amine and aryl layers to modulate the adsorption of protein was investigated using fluorescently labelled protein, bovine serum albumin-fluorescein isothiocynate (BSA-FITC) and fluorescence microscopy. TGD, para methyl phenyl (MP), para hexyl phenyl (HP) and para polyethylene glycol phenyl (PEG)-modified GC surfaces promoted protein adsorption relative to as-prepared GC, whereas n-hexylamine (HA) and polyethylene glycol diamine (PGD) layers reduced protein adsorption. The assembly of two types of NPs, aldehyde/sulfate-functionalised PS and citrate-capped gold NPs, onto amine-containing modifiers layers was examined. Citrate-capped gold NPs were synthesised and characterised. The surface coverage of the gold NPs was controlled by using different modifiers of different chemical compositions, tuning the modification conditions and adjusting the immersion time, concentration and pH of gold NP solution. Approaches to creating patterns of modifiers in pre-determined spatially defined locations on GC and PPF surfaces using poly(dimethyl)siloxane (PDMS), poly(vinyl)alcohol (PVA) and thin metal films were investigated. With the "fill-in" approach using PDMS, the smallest pattern of modifiers was the parallel lines with a line width of 20 µm and straight edges and was created by performing electrochemistry in PDMS microchannels which has not been previously investigated. Visualisation techniques, based on optical and scanning electron microscopy, were demonstrated for the molecular patterns.

surfaces

carbon

amines

aryl diazoniums

nanoparticles

patterning

Interface Studies of Small-Molecule Organic Photovoltaics; Surface Modifications, Electron Donor Texturing, and Co-Facial Variations at the Donor/Acceptor Heterojunctions

Placencia, Diogenes

January 2011

The role of the oxide/organic and organic/organic interfaces in small-molecule planar-Heterojunction (PHJ) photovoltaics was investigated with three interrelated projects: i) indium-tin oxide (ITO) bottom contact electrodes were modified with gold nanoparticles (Au-NPs) to improve rates of charge-transfer at the donor/oxide interface, ii) donor layers in OPVs were textured to increase charge generation at the organic/organic' interface, and iii) the effect of co-facial overlap on device performance via tuning of the electron acceptor orientation at the organic/organic interface. The modification of ITO with Au-NPs showed increased performance in small-molecule OPVs when compared to non-processed ITO devices due to the interactions between the Au-NPs and the donor material. Textured TiOPc increased overall device performance by a factor of 2X via the increased surface area, near-IR absorption, and increased mobilities. Modified and un-modified PTCDA acceptors showed that co-facial overlap at the organic/organic' interface is a large determinant in device performance, while the performance in small-molecule planar-heterojunction photovoltaics were severely affected by the pre-treatment process, most likely due to the particular interactions between the oxide and the donor material.

phthalocyanine

titanyl phthalocyanine

Chemistry

gold nanoparticles

photovoltaics

Nanoparticulate delivery systems for 5-fluorouracil

Keating, Siobhan

January 2000

No description available.

615.1

An integrated ecotoxicological assessment of the engineered nanoparticles, C₆₀ fullerenes, in different life stages of marine mussels, Mytilus edulis

Al-Subiai, Sherain Naser

January 2011

Studies were undertaken to determine ecotoxicological effects of model manufactured or engineered nanoparticles (ENPs), either alone or in combination with a representative polycyclic aromatic hydrocarbon (i.e. PAHs: fluoranthene) at different levels of biological organisation (viz. biochemical, histological and behavioural levels) in a sentinel, widely distributed marine invertebrate species, Mytilus edulis. With the current and predicted levels of pollution in the marine and coastal environment, there is an urgent need to establish the potential effects of persistent and emerging contaminants which includes ENPs and PAHs, to protect human and environmental health. In this study, initially, it was aimed to optimise the induction of biotransformation enzyme P-450 as a robust biochemical tool and good progress (chapter 3) was made to standardise P-450 in mussel. Due to certain technical and logistic limitations however we could not apply measurement of P-450 as potential biochemical biomarkers in this species. The possibility of using glutathione levels instead in the cell-free component of haemolymph samples as an indicator of oxidative stress, in an analogous way to that used in mammals was evaluated (chapter 4). The evidence suggested that cell-free haemolymph samples collected from adductor muscle of Mytilus edulis may be significantly contaminated with intracellular contents of myocytes of this organ (i.e. adductor muscle) and adductor muscle tissue is more generally useful to determine glutathione system responses. The validation study of different assays using copper as a relevant environmental contaminant (chapter 5) suggested the existence of clear relationships between genotoxic (as determined by induction of DNA strand breaks using the Comet assay) and higher level effects. The results further suggested the feasibility of adoption of an integrated approach and robustness of selected biomarkers to evaluate short and long-term toxic effects of pollutants. A multiple biomarker approach was then used to determine the potential interactive effect of C60 fullerenes in combination with fluoranthene. Where appropriate analytical tools (i.e. ICP-MS, GC-MS) were used to determine the levels of contaminant exposure and characterise the properties of the ENPs. The combined exposure of fluoranthene and C60 fullerenes produced enhanced biological damage at approximately at an- “additive” rather than synergistic level, which appeared to be as a result of oxidative stress (chapter 6). The final experiments were carried out in both the early and adult life stages to test the potential toxicity resulting from photochemical transformation of C60 fullerenes in Mytilus edulis (chapter 7). In general, the results showed, for the first time, genotoxic and developmental impact of the photochemically transformed C60 fullerenes at different life stages of marine mussel. Further research is required to identify the degraded products of C60 fullerenes and to understand the mechanism by which fresh and aged C60 fullerenes induces biological responses including oxidative stress and affect ecologically relevant aquatic organisms at different life stages. The thesis has taken the opportunity to discuss (chapter 8) the importance of applications of biological responses in hazard and risk assessment posed by anthropogenic chemicals in a broader context.

577.27

Microfluidic synthesis of block copolymer nanoparticles for drug delivery

Bains, Amandeep Singh

04 May 2016

In this dissertation, we studied two-phase microfluidics as a platform for the controlled synthesis of drug delivery polymeric nanoparticles (PNPs). The block copolymer we studied was poly(ε-caprolactone)-block-poly(ethylene oxide) (PCL-b-PEO). The anticancer drug we studied was paclitaxel (PAX). First, we explored microfluidic control of nanoparticle structure (size, morphology, and core crystallinity) on PCL-b-PEO PNPs without loaded PAX. We demonstrated the reproducible variability of PCL-b-PEO nanoparticle size and morphology. Microfluidic control of nanoparticle size and morphology was found to arise from the interplay of flow-induced particle coalescence and breakup. Next, we demonstrated the linear dependence of PCL core crystallization on flow-rate. We attributed this dependence of PCL core crystallization on flow-induced crystallization. We then used our microfluidic device to control PAX-loaded PNP structure and function (small molecule loading efficiency, diffusional release kinetics, and cytotoxicity). At low drug loading ratios (r < 0.1), we demonstrated reproducible variability of PAX-loaded PNP size and morphology. With increasing flow rate we were able to manufacture PNPs of high aggregation number. We were also able to reproducibly demonstrate the linear dependence of PCL core crystallinity on flow rate. Furthermore, PAX loading efficiency was dependent on PNP size and morphology. Formulations which consisted of cylindrical and lamellar type morphologies typically had higher PAX loading efficiencies, than formulations which consisted of spherical structures. Next, we studied diffusional PAX release, increasing core crystallinity correlated with slowing diffusional PAX release kinetics. At high drug loading ratios (r > 0.1), we demonstrated reproducible control of PAX-loaded PNP structure and function. PCL core crystallinity was a major factor influencing PNP size and morphology. Samples with high core crystallinity formed PNP structures with low internal curvature. Furthermore, core crystallization had a large influence on PAX loading efficiency; as samples with high PAX loading efficiency correlated with low PCL core crystallinity. With respect to diffusional PAX release, we found that increasing PCL core crystallinity correlated with slowing diffusional PAX release kinetics. Next, we studied the cytotoxicity of our PAX-loaded PNPs using the MCF-7 cancer cell line. Due to the complex nature of the interactions between our PAX-loaded PNPs and the cancer cells, we were not able to elucidate the exact influence of flow rate on PNP cytotoxicity. / Graduate

nanoparticles

drug delivery

block copolymer

micelle