Biochemical Characterization of Polycationic Nucleic Acid Delivery Vectors

Fichter, Katye M.

25 August 2008

No description available.

Biochemistry

Cellular Biology

Chemistry

Molecules

nonviral gene delivery

confocal microscopy

lanthanide imaging

Synthesis, Structure, And Characterization Of Rare Earth(Iii) Transition Metal Cyanides; Lanthanide(Ii) And Metallocene Amidotrihydroborates

Wilson, Duane C.

11 February 2009

No description available.

Chemistry

rare earth

lanthanide

transition metal

cyanide

Iron

amidotrihydroborate

hydrogen storage

metallocene

NH2BH3

The Synthesis, Structure and Characterization of Extended Cobalt Ruthenium Carbonyl Compounds

Potratz, Christopher M.

03 September 2010

No description available.

Chemistry

alkali

alkaline earth

lanthanide

transition metal

isocarbonyls

Fischer-Tropsch

hydroformylation

Metal Oxide Nanoparticles: Optical Properties and Interaction with Chemical Warfare Agent Simulants

Gordon, Wesley Odell

01 December 2006

Materials with length scales in the nanometer regime demonstrate properties that are remarkably different from analogous bulk matter. As a result, researchers are striving to catalog the changes in properties that occur with decreasing size, and more importantly, understand the reason behind novel nanomaterial properties. By learning the true nature of nanomaterials, scientists and engineers can design better materials for a variety of applications. Inert gas-phase condensation synthesis of metal oxide nanoparticles was used to develop materials to explore the optical and chemical properties of metal oxide nanoparticles. One potential application for nanomaterials is use in optical applications. The possibility of interparticle energy transfer was investigated for lanthanide-doped yttrium oxide nanoparticles using laser spectroscopy. Experimental evidence collected with this study indicates that interparticle, lanthanide-mediated energy transfer may have been observed. In addition, lanthanide-doped gadolinium oxide nanoparticles were synthesized and investigated with optical spectroscopy to identify the best potential candidates for bioanalytical applications of this material. The influence of particle annealing and dopant concentration were also studied. Nanoparticle film structure was investigated with scanning electron microscopy. Two different film structures composed of oxide nanoparticles were found to grow under different synthesis conditions. The film structure was found to be determined by the degree of particle aggregation in the gas phase during synthesis. Aggregation of the particles was found to be controlled by a combination of gas pressure and properties. Chemical properties of metal oxide nanoparticles also are very important. Reflection-absorption Infrared Spectroscopy and vacuum surface analytical techniques were used to explore the chemistry of the chemical warfare agent dimethyl methylphosphonate (DMMP) on yttrium oxide as well as other metal oxide nanoparticles. DMMP was found to dissociate at room temperature on several types of metal oxide nanoparticles. Hydroxyl groups were found to be critical for the adsorption of DMMP onto the particles. Finally, the reactivity of the nanoparticles was found to increase with decreasing particle size. This was attributed to a relative increase in the number of high-energy surface defects for the smaller particles. / Ph. D.

phosphor

lanthanide

energy transfer

size-dependent reactivity

yttrium oxide

dimethyl methylphosphonate

Design of optical characteristics of ceria nanoparticles for applications including gas sensing and up-conversion

Shehata, Nader

13 December 2012

This thesis investigates the impact of doping on the optical and structural characteristics of cerium oxide (ceria) nanoparticles synthesized using chemical precipitation. The dopants selected are samarium and neodymium, which have positive association energy with oxygen vacancies in the ceria host, and negative association lanthanides, holmium and erbium, as well as two metal dopants, aluminum and iron. Characteristics measured are absorption and fluorescence spectra and the diameter and lattice parameter of ceria. Analysis of the characteristics indicates qualitatively that the dopant controls the O-vacancy concentration and the ratio of the two cerium ionization states: Ce+3 and Ce+4. A novel conclusion is proposed that the negative association lanthanide dopants can act as O-vacancies scavengers in ceria while the O-vacancy concentration increases in ceria doped with positive association lanthanide elements. Doped ceria nanoparticles are evaluated in two applications: dissolved oxygen (DO) sensing and up-conversion. In the first application, ceria doped with either Sm or Nd and ceria doped with aluminum have a strong correlation between the fluorescence quenching with the DO concentration in the aqueous solution in which the ceria nanoparticles are suspended. Stern-Volmer constants (KSV) of doped ceria are found to strongly depend upon the O-vacancy concentration and are larger than some of the fluorescent molecular probes currently used to measure DO. The KSV measured between 25-50oC is found to be significantly less temperature dependent as compared to the constants of commercially-available DO molecular probes. In the second application, up-conversion, ceria nanoparticles doped with erbium and an additional lanthanide, either Sm or Nd, are exposed to IR radiation at 780 nm. Visible emission is only observed after the nanoparticles are calcinated at high temperature, greatly diminishing the concentration of O-vacancies. It is concluded that O-vacancies do not play a dominant role in up-conversion, unlike that drawn for down-conversion, where the fluorescence intensity is strongly correlated with the O-vacancy concentration. Correlations between annealing temperatures, dopant, and dopant concentrations with the power dependence of up-conversion on the pump and the origin of the intensities of the visible emission are presented. These studies show the promise of doped ceria nanoparticles. / Ph. D.

Ceria nanoparticles

lanthanide dopants

oxygen vacancies

fluorescence quenching

oxygen sensing

up-conversion

Transition Metal Complexes Anchored on Europium Oxide Nanoparticles

Zapiter, Joan Marie Diangson

06 January 2014

Polypyridyl transition metal complexes containing ruthenium, rhodium and iridium centers are mainly studied due to their light absorbing and emitting properties. Lanthanide oxides such as europium oxide absorb light as well and exhibit strong luminescence and long lifetimes. The optical properties of these materials were significant especially in solar energy utilization schemes and optical applications. Energy transfer across a surface is important in several applications including phosphors and biomedical applications. Excited states of metal complexes with a carboxylate-containing ligand such as deeb = diethyl-2,2'-bipyridine-4,4'-dicarboxylate were studied on nanoparticle surfaces. In this work, [Rh(deeb)2Cl2](PF6), [Ir(deeb)2Cl2](PF6) and [Ir(deeb)2(dpp)](PF6)3 were synthesized using the building block approach. The metal complexes were characterized using 1H NMR spectroscopy, mass spectrometry, electronic absorption spectroscopy and electrochemistry. The 1H NMR spectra of the complexes were consistent with those of their ruthenium analogs. Mass spectra contain fragmentation patterns of the (M-PF6)+ molecular ion for [Rh(deeb)2Cl2](PF6) and [Ir(deeb)2Cl2](PF6), and (M-3PF6)3+ molecular ions for [Ir(deeb)2(dpp)](PF6)3. The electronic absorption spectrum of [Rh(deeb)2Cl2](PF6) shows a maximum at 328 nm, which is assigned as 1π→π*transition. The electronic absorption spectrum of [Ir(deeb)2Cl2](PF6) shows maxima at 308 nm and 402 nm, which are assigned as 1π→π* and metal-to-ligand charge transfer transitions, respectively. The [Ir(deeb)2(dpp)](PF6)3 complex exhibits peaks due to 1π→π* transitions at 322 nm and 334 nm. [Rh(deeb)2Cl2](PF6) has emission maxima from the 3LF state at 680 nm and 704 nm for the solid and glassy solutions at 77 K, respectively. [Ir(deeb)2Cl2](PF6) has emission maxima from the 3MLCT state at 538 nm in acetonitrile and 567 nm in the solid state at room temperature, with lifetimes of 1.71 μs and 0.35 μs, respectively. [Ir(deeb)2Cl2](PF6) has an unusually higher quantum yield than analogous compounds. [Ir(deeb)2(dpp)](PF6)3 has emission maxima from the 3IL state at 540 nm in acetonitrile and 599 nm in the solid state at room temperature, with lifetimes of 1.23 μs and 0.14 μs, respectively. Cyclic voltammetry of [Ir(deeb)2Cl2](PF6) and [Ir(deeb)2(dpp)](PF6)3 yield reversible and quasi-reversible couples corresponding to deeb ligand and Ir3+/+reductions, respectively. Attachment of the complexes were conducted by equilibration of complex solutions in acetonitrile with europium oxide nanoparticles. Europium oxide nanoparticles, which were synthesized by gas-phase condensation, have 11-nm diameters and exhibit sharp f-based luminescence in the visible and near IR regions. EDX, TEM, IR and reflectance spectroscopy measurements indicate substantial coating through various modes of attachment of the nanoparticle surface by the metal complexes while retaining the excited state properties of the metal complexes. Surface adsorption studies indicate monolayer coverage of the nanoparticle surface by the metal complexes, consistent with limiting surface coverages of previously reported analogous systems. Eu2O3 nanoparticles modified with [Rh(deeb)2Cl2]+ exhibit minimal to no energy transfer from emission spectra, and a reduction in the lifetime at 77K could be due to the rhodium complex preventing the excitation of Eu3+. Upon attachment of the Ir complexes [Ir(deeb)2Cl2]+ and [Ir(deeb)2(dpp)]3+ on as-prepared nanoparticles, Eu3+ luminescence was observed for nanoparticles modified with iridium complexes at room temperature, which could be due to energy transfer among other possibilities. Efficiencies of 68% and 50%, and energy transfer rate constants of 1.1 x 10-5 and 1.0 x 10-5 were calculated from lifetime data for [Ir(deeb)2Cl2]+ and [Ir(deeb)2(dpp)]3+ on Eu2O3 nanoparticles, respectively. Since iridium complexes are used as components of light-emitting diodes, europium oxide nanoparticles modified with iridium complexes have potential in optical applications which make studies of these compounds interesting. / Master of Science

lanthanide

spectroscopy

photochemistry

energy transfer

luminescence

inert-gas condensation

ruthenium

rhodium

iridium

bipyridine

Investigation into the development of novel lanthanide-based luminescent colorants for application to textiles and paper materials

Lewis, D.M., Broadbent, P.J., Rigout, M.L.A., Carr, C.M., Seaton, Colin C., Swift, Thomas

24 February 2023

Yes / This article describes the synthesis and application of lanthanide-based luminophores for visualisation under short wavelength ultraviolet (UV) activation (typically 254 nm). Luminophores are chemical compounds which re-emit light of longer wavelength than typical fluorescence and phosphorescence, following photoexcitation, because of efficient energy transfer from the ligands to the lanthanide ion emission levels. The luminophores described in this article are all derived from europium and terbium metal complexes and cover the complete colour gamut. Selection of appropriate ligands allows for water solubility or water insolubility (if required pigment or disperse “dye” applications). Similar to dyeing or printing processes, the anionic complexes can be applied to polyamide fibres or to cellulosic fibres, whereas dispersions of the non-ionic complexes are suitable for polyester or cellulose acetate fibre application. The water-soluble derivatives are also suitable for ink-jet printing and the water-insoluble derivatives are suitable for lithographic or intaglio paper printing. The novel complexes are excited by radiation below 300 nm and thus cannot be activated by sunlight (the earth's atmosphere prevents light below about 300 nm reaching the surface). Accordingly, the photo-stability of the dyed materials and prints obtained is excellent. These materials could be used in security marking applications, for example bank-notes and passports, where they could replace the current fluorophores that are rendered visible under near UV light (typically 365 nm) illumination but exhibit relatively poor photo-stability. The development of an RGB (red, green and blue) colour palette for inkjet printing based on these innovative luminophores will significantly support the design of digitally printed security features. / The research was part funded by Inovink Ltd and theWorshipful Company of Clothworkers of the City of London.

Lanthanide-based luminescent colorants

Luminophores

Ultraviolet (UV) light

Textiles

Paper materials

Approche moléculaire par le procédé sol-gel de nanoparticules de TiO2 dopées et/ou fonctionnalisées : applications en imagerie médicale et en catalyse d'oxydation / Molecular approach for the syntesis of doped and/or hybrid titania nanoparticles via a sol gel process : applications in medical imaging and oxidation catalysis

Mendez, Violaine

06 January 2010

Un procédé sol-gel développé au laboratoire a été appliqué à des précurseurs hétéroleptiqueset/ou hétérométalliques pour l’élaboration de nouveaux matériaux hybrides et/ou dopés.Des nanoparticules de TiO2 dopées par le gadolinium et l’europium ont été obtenues sous formede nanocristallites d’anatase par ce procédé basse température. Leurs performancesmagnétiques et luminescentes ont été évaluées afin de pouvoir les utiliser comme agents decontraste pour l’imagerie médicale. L’utilisation d’un précurseur hétérométallique ethétéroleptique contenant à la fois du titane, du gadolinium et du PABA a pu conduire à laformation de matériaux dopés et hybrides en une seule étape. L’utilisation future de cesmatériaux dans le domaine biomédical est envisagée.La deuxième partie de ce travail a consisté en l’élaboration de supports hybrides TiO2(citrate) en appliquant le même procédé de co-hydrolyse à un nouvel alcoxyde de titane comportant le ligand citrate. Plusieurs degrés de fonctionnalisation organique de surface ont été obtenus par la modification des quantités relatives des précurseurs de départ. En mettant simplement en présence ces supports avec des solutions aqueuses de sels d’or ou d’argent, les fonctions citrates ont permis la formation de particules métalliques directement à la surface des supports. Ces matériaux M/TiO2 ont été utilisés en tant que catalyseurs dans l’époxydation du transstilbène en phase liquide et ont permis d’améliorer la connaissance des mécanismes de cette réaction aérobie. / A new and relevant sol-gel process has allowed us to prepare new hybrid materials. Titania nanoparticles with lanthanides doping agent (gadolinium and europium) were obtained as anatase nanocrystallites via our low-temperature process. Their magnetic and luminescent properties have been tested in order to use them as contrast agent in medical imaging. A doped and hybrid material has also been obtained and its NH2 groups at the surface will be used in thebio-medical field. The second part of this work has consisted in the preparation of TiO2(citrate) hybrid supports viaa new titanium alkoxide that contains a citrate ligand. Several surface citrate density had been obtained by changing the precursor’s initial relative amounts. Then the simple contact between these hybrid supports and aqueous solutions of silver or gold ions led to the formation of metallic particles directly on the surface support thanks to the presence of the citrate groups, which are known to be reducing agent. These M/TiO2 materials were then tested as catalysts in the aerobic epoxidation of trans-stilbene in the liquid phase. Through this study, we were able to improve our knowledge in this reactionmechanism.

Nanoparticules

Hybrides

Procédé sol-gel

TiO2

Or

Argent

Catalyse

Oxydation en phase liquide

Dopage lanthanide

Nanoparticles

Hybrid

Sol-gel process

Titania

Gold

Silver

Catalysis

Liquid phase oxidation

Lanthanide doping agent

540

Synthèses de nanoparticules hybrides : de nouveaux agents pour le diagnostic et la thérapie combinés / Synthesis of hybrids nanoparticles : new agents for diagnosis and therapy

Mutelet, Brice

19 September 2011

La miniaturisation des systèmes a montré qu’à l’échelle nanométrique, les matériaux possèdent des propriétés différentes de leur état massif. Aujourd'hui, la synthèse d’objets de taille nanométrique est en parfaite adéquation avec les systèmes biologiques pour des applications médicales. La possibilité pour les chimistes de combiner dans un même « nano-objet » différent types de matériaux aux propriétés complémentaires a ouvert la voie au développement de nanoparticules multifonctionnelles pour des applications biologiques. C’est dans ce domaine, en utilisant les propriétés remarquables des terres rares que le LPCML de l’Université de Lyon en collaboration avec le laboratoire MATEIS de l’INSA de Lyon a pu mettre au point des nanoparticules hybrides multifonctionnelles ayant une structure cœur/coquille en combinant un cœur inorganique d’oxyde de lanthanide protégé par une coquille organique composée de polysiloxanes. L’utilisation d’un cœur d’oxyde de terre rare permet de disposer à la fois d’outils de détection (optique avec Eu et Tb, IRM avec Gd, Dy et Ho ou en scintigraphie avec Ho) et d’agent thérapeutique avec Gd et Ho. Après avoir longuement étudié les propriétés comme agent de contraste et de thérapie par capture neutronique du gadolinium, nous nous sommes intéressés aux propriétés atomiques de l’holmium qui après irradiation neutronique émet des rayonnements  et - potentiellement intéressants pour un traitement en curiethérapie. Le travail de thèse présenté ici rend compte de l’étude réalisée d’une part sur les propriétés optiques et magnétiques de ces nanoparticules hybrides à base d’oxyde de terre rare et d’autre part sur les possibilités d’applications médicales avec l’utilisation d’holmium. / The everlasting search for the miniaturization of the processes has shown that at the nanometer scale materials exhibit different properties than from the bulk. Today, the synthesis of nano-sized objects is in perfect harmony with biological systems for medical applications. The opportunity for chemists to combine into a single nano-oject different kind of materials with complementary properties has opened the way for the development of multifunctional nanoparticles for biological applications. In this area, using the remarkable properties of rare earths, LPCML laboratory from Lyon University in collaboration with MATEIS laboratory from INSA-Lyon was able to develop multifunctional hybrid nanoparticles with a core/shell structure by combining an inorganic rare earth oxide core coated by a polysiloxane shell. The using of a lanthanide in the core enables the combination of detection tools (optical with Eu and Tb, MRI with Gd, Dy and Ho or scintigraphy with Ho) and therapeutic agents with Gd and Ho. After having studied the properties of gadolinium as a contrast and neutron capture therapeutic agent, we were interested in atomic properties of holmium after neutron irradiation which emits  and - radiations, potentially interesting for scintigraphic imaging and brachytherapy. The thesis presented here reports studies on the one hand on optical and magnetic properties of these hybrid nanoparticles and on the other hand the possibilities of medical applications by using holmium-based particles.

Nanoparticule hybride

Nanoparticule fonctionnelle

Coeur inorganique

Structure coeur-coquille

Oxyde de lanthanide

Polysiloxane

Application biomédicale

Scintigraphie

Curiethérapie

Terre rare

Hybrid nanoparticle

Functional nanoparticle

Core-shell structure

Lanthanide oxide

Siloxane polymer

Biomedical application

Scintigraphy

Curietherapy

Inorganic core

Rare earth

620.115 072

Synthèse de ligands porteurs de chromophores et étude de la complexation des lanthanides.

Deneil, Christine

18 March 2008

Voir fichier joint.

relaxivity/relaxivite

lanthanide/lanthanide

organic ligand/ligand organique

calix[4]arene/calix[4]arene

organic synthesis/synthese organique

hydroxamate/hydroxamate

luminescence/luminescence

chromophore/chromophore

complexation/complexation