The Assessment of Effects of Carbon Quantum Dots on Immune System Biomarkers Using RAW 264.7 Macrophage Cells

Fowler, Jodi

January 2020

>Magister Scientiae - MSc / Nanotechnology is a rapidly growing field of research. Due to major innovations brought about by developments in nanotech, several consumer products are currently available containing nanomaterials. The increase of nanomaterial production and use is accompanied by the increased potential of human, plant and animal exposure to these nanomaterials. As a relatively new nanomaterial, carbon quantum dots (CQDs) are being extensively used and researched due to its unique properties. Although many studies have assessed the toxic potential of CQDs, and found them to exhibit low toxicity, there is lack of work assessing the effects on the immune system. In the present study, RAW 264.7 murine macrophages were used as model to assess the immunomodulatory potential of CQDs. RAW cells exposed to varying concentrations of CQDs (0-500μg/ml), showed that CQDs caused a reduction at cell viability. In the absence of a mitogen CQDs, induced an inflammatory response by stimulating the release of various cytokines and chemokines such as, TNFα, MIP-1α, MIP-1β, MIP-2, IP-10, G-CSF, GM-CSF, and JE.

Nanotechnology

Biomedicine

Nanoparticles (NPs)

Nanomaterials

Nanotoxicology

Immunotoxicity

Vivo

vitro

Development and potential applications of nanomaterials for arsenic removal from contaminated groundwater.

Kumar, Rajender

January 2011

In this study, a magnetic nanomaterial was used for the binding of anionic arsenic species from contaminated groundwater. Iron oxide (Fe3O4) magnetic nanoparticles (NPs) and the surface modified Fe3O4 NPs with 3-aminopropyl-triethoxysilane (3-APTES), Trisodium citrare (TSC) and Chitosan were synthesized with the co-precipitation method. Structural characterizations showed that the four kinds of NPs had different sizes an average particle range size of 15-20 nm was observed with Transmission Electron Microscopy. X-ray diffraction was used to identify the crystalline structure of synthesized Fe3O4 and surface modified NPs. Molecular structure and functional groups present in synthesized magnetic NPs Fe3O4 were identify with infrared analysis. The synthesized Fe3O4 NPs and surface coated NPs were used for determine the binding capacity of Arsenic ions from the synthetic groundwater. The binding of As(III) increased as the dissolved As(III) concentration increased in the solution. From the experiments it was found chitosan-coated NPs are best than other coated and uncoated NPs for arsenite removal from the solution. It was found that if only As(III) ions were present in the water without other anions and cations the binding capacity of the magnetic NPs is very high. The binding capacity of As ions was decreased with presence of other anions and cations in the groundwater because they interfere with arsenic binding sites which presence on the magnetic NPs.

Iron oxide nanoparticles (NPs)

surface modification

structural charcaterisation

Arsenic species

Water Engineering

Vattenteknik

Auto-assemblage de matériaux méso-structurés / Self-assembly of meso-structured materials

Schmitt, Julien

06 October 2014

Les matériaux méso-structurés sont des matériaux à porosité contrôlée, issus de synthèses de chimie sol/gel entre micelles de tensioactifs et précurseur inorganique, le plus souvent de silice. Parmi ces matériaux, le SBA-15, formé en milieu super-acide à partir de P123 (un copolymère tribloc) comme tensioactif et de TEOS comme précurseur inorganique de silice, est un des plus étudiés. La synthèse de ce matériau a été étudiée par diffusion des rayons X à petits angles (SAXS) in situ, et a permis de décrire qualitativement et quantitativement les mécanismes d’auto-assemblages entre micelles de tensioactifs et particules silicatées. Spécifiquement, nos résultats ont montré que l’hydrolyse-condensation du TEOS en solution a permis la formation d’oligomères de silice, qui interagissent avec la couronne des micelles sphériques de P123, pour progressivement former des micelles hybrides cylindriques organiques/inorganiques, qui vont ensuite précipiter en une mésophase hybride 2D-hexagonale. Ce modèle de synthèse est appelé « transition sphères-cylindres ». De plus, afin de comprendre les mécanismes de formation du matériau à toutes les échelles, nous avons étudié l’influence des conditions de synthèse sur la morphologie des grains de matériau méso-structurés. En effet, nous avons montré que sans agitation pendant la synthèse, les grains de matériaux présentent une forme d’équilibre qui dépend fortement de la température de synthèse. En fonction de la température, il est donc possible de former des matériaux hybrides de forme grains de riz, bâtons (courts ou longs) ou mêmes sous forme de tores. Nous proposons un modèle théorique qui permet d’expliquer l’ensemble des morphologies observées, en fonction des tensions de surfaces et des énergies de courbures de cristal-liquide 2D-hexagonal lors de la précipitation de la mésophase hybride. Nous appuyons ce modèle théorique sur des études en diffusion des rayons X à très petits angles (USAXS), qui permettent d’étudier la croissance des grains. Grâce à ces études, nous proposons une description très complète de la formation du matériau SBA-15. Fort de ces connaissances, nous avons pu, grâce à de nouvelles études de SAXS in situ, appliquer le modèle de précipitation de type « transition sphères-cylindres » à d’autres matériaux, issus de tensioactifs non-ioniques fluorés, et ainsi expliquer la formation de matériaux dits « bimodaux », c’est-à-dire issus d’un mélange entre P123 et un tensioactif fluoré(Rf₈(EO)₉ et qui présentent deux ordres poreux bien définis. Enfin, nous avons cherché à utiliser nos connaissances pour la fabrication de matériaux innovants, en remplaçant la solution micellaire par des émulsions dopées en nanoparticules d’or (NPs), afin de fabriquer des matériaux hybrides dopés en NPs. / Meso-structured materials are materials with a well-controlled porosity, designed from sol/gel syntheses between surfactant micelles and an inorganic precursor, most often a silica precursor. Among them, the SBA-15 material, formed in super-acid solution from P123 (a tri-block copolymer) as surfactant and TEOS a silica precursor, is one of the most studied. Synthesis of this material has been studied by in situ Small Angle X-Ray Scattering (SAXS), which allowed to describe both qualitatively and quantitatively the self-assembly mechanisms between surfactant micelles and silica particles. In details, our results showed that TEOS hydrolysis-condensation allow the formation of silica oligomers that interact with the corona of the spherical micelles of P123, and progressively the micelles reshape in hybrid organic/inorganic cylindrical micelles. The hybrid micelles, first free in solution, eventually precipitate in a hybrid 2D-hexagonal mesophase. This model of synthesis is called “sphere-to-rod transition”. Moreover, in order to understand the material mechanisms of formation at every length scales, we studied the influence of the synthesis conditions on the morphology of the meso-structured material grains. Indeed, in agreement with a previous study, our results show that if the synthesis is made without stirring, the material grains has an equilibrium shape that strongly depends on the synthesis temperature. By changing the temperature, one can form hybrid materials with a “rice grain” shape, or a (short or long) rod shape, or even a torus shape. We propose a theoretical model to explain all the observed morphologies, model that takes into account surface tensions and curvature energy of the newly formed 2D-hexagonal liquid-crystal at the precipitation of the hybrid mesophase. We measured the nucleation and growth of the grains by Ultra Small Angle X-Ray Scattering (USAXS). Thanks to all these studies, we present a complete description of the formation of the SBA-15 material. Our knowledge were used to describe new in situ SAXS measurements of new materials: our “sphere-to-rod transition” model was able to describe the formation of two materials, form two fluorinated surfactants and allowed to explain the formation of a “bimodal” material, which means a material with two well-defined porous order, that is synthesized from a mix of two surfactant (P123 and (Rf₈(EO)₉). Finally, we tried to use our knowledge to form innovative materials, by replacing the micellar solution as template by an emulsion doped in gold nanoparticles (NPs) to form hybrid materials doped in NPs.

Matériaux méso-structurés

Auto-assemblage

SAXS in situ

Nanoparticules d’or (NPs)

TEOS

TMOS

Tensioactif

Précurseur de silice

Meso-structured materials

Self-assembly

SAXS in situ

Gold nanoparticles (NPs)

TEOS

TMOS

Surfactant

Silica precursor

Innovative NIR fluorescent probes for an improved tumor detection in vivo / Innovative Nahinfrarot (NIR) Fluoreszenzproben für eine verbesserte Tumordetektion in vivo

Mathejczyk, Julia Eva

15 December 2011

No description available.

570 Biowissenschaften, Biologie

MED 372

Medicine

Autofluoreszenz

Lebensdauer

pH-sensitiver Farbstoff

Polystyren Naopartikel (NPs)

in vivo

Brusttumor Xenograft

Nacktmaus

Herceptin

autofluorescence

lifetime (LT)

pH-sensitive dye

polystyrene nanoparticles (NPs)

in vivo

breast tumor xenograft

nude mouse

Herceptin

30.30

44.81