Novel bisnaphthalimidopropyl polyamine derivatives : their mode of action in a breast cancer cell system

Barron, Gemma A.

January 2010

The synthesis and characterisation of novel bisnaphthalimidopropyl polyamine (BNIPP) derivatives, has gained pace over the last couple of years, as they have enhanced aqueous solubility, without loss of biological activity, in contrast to parent bisnaphthalimide derivatives. Recent work has shown that bisnaphthalimidopropyl spermidine (BNIPSpd) bis-intercalates to DNA, induces oxidative DNA damage, depletes polyamine levels and causes cell death, by apoptosis, in human colon cancer CaCO-2 and HT-29 cells. The aim of this thesis was to synthesise new BNIPP derivatives to highlight the important structural features required for biological activity, particularly, bisnaphthalimidopropyl functionality, and investigate their subsequent modes of action in breast cancer MDA-MB-231 and breast epithelial MCF-10A cells. Initially, work focused on determining the DNA binding affinities and biological activity of BNIPP derivatives. All BNIPP derivatives, except bisphthalimidopropyl diaminodecane (BPHPDadec) and mononaphthalimidopropylamine (NPA) (Δ Tm values of 15.8 and 10.2 °C, respectively, C50 values of > 10 μM, IC50 values of > 40 μM), exhibited strong DNA binding affinities and cytotoxic properties in both cell lines. Results indicate that BNIPP derivatives interact with DNA by bis-intercalation suggesting, therefore, that BNIPP derivatives target DNA. For the first time, an investigation into the mechanism of cellular entry, via the polyamine transport (PAT) system, was studied. However, none of the BNIPP derivatives utilised the MGBG-specific PAT system, suggesting that BNIPP derivatives utilise other modes of cellular entry. Two BNIPP derivatives, BNIPSpd and BNIPDaCHM, were further investigated, and results show that these derivatives significantly induced a dose dependent increase in DNA strand breaks from ≥ 0.1 μM, after 4 hours. BNIPSpd and BNIPDaCHM (at non toxic concentrations) also inhibited the repair of oxidative (H2O2) and methylative (MMS)-induced DNA strand breaks. Based on phosphatidylserine exposure and membrane integrity analyses, early apoptotic cell death was determined as a mode of cell death utilised by both BNIPSpd and BNIPDaCHM (5 μM), after only 0.5 hours treatment in MDA-MB-231 cells. Interestingly, BNIPDaCHM was identified, using HDAC assay kits, as a potent and selective SIRT2 enzyme inhibitor, thus, identifying, a novel structural backbone for the selective inhibition of HDAC enzymes.

615.1

Processing melt blended polymer nanocomposites using a novel laboratory mini-mixer : development of polymer nanocomposites in the melt phase using a novel mini-mixer

Khan, Atif Hussain

January 2012

Research into the processing conditions and parameters of polymeric nanocomposites has always been challenging to scientists and engineers alike. Many have developed tools and procedures to allow materials to be exploited and their properties improved with the addition of nanofillers to achieve the desired end material for various applications. Initial trials are mostly conducted using conventional small scale experiments using specialised equipment within the laboratory that can replicate the larger industrial equipment. This is a logical approach as it could save time and costs as many nanocomposites are relatively expensive to produce. Experiments have previously been done using the likes of the Haake twin screw extruder to manufacture nanocomposites within the laboratory but this research project has used a novel minimixer specifically developed to replicate mixing like large twin screw extrusion machines. The minimixer uses a twin paddle system for high shear mixing in conjunction with a single screw thus theoretically allowing an infinitely long recirculation. It is this ability to mix intensely whilst allowing for as long as desired recirculation which enables the replication in this very small mixer (10-30g capacity) of the mixing conditions in a large twin screw extruder. An added feature of the minimixer is that it can undertake inline data analysis in real time. The main experiments were conducted using a comprehensive DOE approach with several different factors being used including the temperature, screw speed, residence time, clay and compatibiliser loading and two polymer MFI's. The materials used included PP, Cloisite 20A, Polybond 3200, PET, Somasif MTE, Polyurethane 80A and Single / Multi-walled Carbon nanotubes. Detailed experimental results highlighted that rheological analysis of the nanocomposite materials as an initial testing tool were accurate in determining the Elastic and Loss modulus values together with the Creep and Recovery, Viscosity and Phase Angle properties in the molten state. This approach was also used in an additional set of experiments whereby the temperature, speed, residence time and compatibiliser were kept constant but the clay loading was increased in 1% wt. increments. These results showed that the G' & G'' values increased with clay loading. Another important finding was the bi-axial stretching step introduced after the processing stage of the nanocomposite materials which highlighted a further improvement in the modulus values using rheological testing. Other tests included using inline monitoring to look into both the viscosity and ultrasound measurements in real time of the molten polymer nanocomposite through a slit die attachment to the minimixer.

620.1

Nanocomposites élastomère-phosphate de zirconium lamellaire : mécanismes de dispersion et mise en oeuvre / Melt compounding of elastomer-zirconium phosphate nanocomposite : mechanisms of dispersion and processing

Hung, Yvong

30 March 2011

L’objectif de cette étude est l’élaboration de nanocomposite à base d’un élastomère de styrène et de butadiène (SBR) par l’ajout d’une dispersion aqueuse (slurry) de nanocharges lamellaires de phosphate de zirconium en phase α (α-ZrP ou ZrP). Les travaux s’attardent d’abord sur le mélange entre le SBR à l’état fondu et le slurry de ZrP en absence de traitement de surface. Différents stratégies d’élaboration sont ensuite envisagées afin d’améliorer la dispersion (intercalation exfoliation) des feuillets de ZrP dans le matériau en couplant le traitement de surface du ZrP et les paramètres de mise en œuvre. Différents traitements de surface sont abordés avec l’utilisation d’un agent intercalant métallique (Na+), de deux intercalants alkylamines (propylamine, octadécylamine) et d’un agent d’exfoliation (hydroxyde de tétrabutylammonium). En parallèle, plusieurs procédés de mise en œuvre générant des écoulements complexes sont utilisés. La complémentarité entre la diffraction des rayons X (DRX), la microscopie électronique en transmission (MET) et la spectroscopie mécanique (DTMA) permet d’obtenir une analyse multi-échelle de l’état de dispersion du ZrP et de proposer des scénarii décrivant les mécanismes de dispersion en fonction des paramètres étudiés. Un effort important est apporté pour la compréhension de la relation structure à l’échelle nanoscopique et les propriétés macroscopiques du matériau. Une étude comparative est ensuite proposée entre les valeurs expérimentales de l’effet de renforcement des matériaux et les prédictions des modèles Krieger-Dougherty et Halpi-Tsai / This work focuses on the melt processing of nanocomposite materials obtained from a synthetic lamellar filler, α-zirconium phosphate (α-ZrP), dispersed within a synthetic rubber of the SBR type. The first step is the melt compounding using aqueous slurry of α-ZrP without any treatment. Following, several kinds of surface modifiers such as sodium cation, alkylamines and tetrabutylammonium hydroxide and different melt processing conditions are investigated to improve the level of dispersion of ZrP platelets into the matrix. X-ray diffraction, transmission electron microscopy and dynamical mechanical method are used as a multi-scale analysis to quantify the state of dispersion of the filler within the nanocomposite. Several mechanisms of dispersion are described depend on the surface modifying treatment and the melt processing parameters and the structure-properties relationship are studied. A comparison between the material reinforcement and two models of predictions, Krieger-Dougherty and Halpin-Tsai are discussed

Nanocomposite

Slurry

Charge lamellaire alpha-ZrP

SBR

Mécanismes de dispersion

Intercalation

Exfoliation

Topochemical Manipulation of Layered Perovskites

Josepha, Elisha A

04 August 2011

Topochemical strategies, techniques that allow one to effectively manipulate the structures of nonmolecular solids once a crystal lattice is established, are effective in the low temperature (< 500 °C) modification of solid state structures, allowing the preparation of nonmolecular compounds not accessible by standard synthetic routes. Some of the techniques, ion exchange, intercalation/deintercalation, have proven to be excellent synthetic methods for preserving specific frameworks. The combination of these techniques can allow one to create a multistep approach that can be used to design new compounds with interesting properties. As an expansion to the field of topotactic reactions, a multistep approach was developed towards the synthesis of the new compounds (A xM0.5Cly)LaNb2O7 (where A = Rb, Cs; M = Fe, Ni; x ≈ 1.5;y ≈ 1) at temperatures below 400oC. The first reaction step involved the ion exchange of the host materials (ALaNb2O7, A = Rb, Cs) to form the products M0.5LaNb2O7 (where M = Fe, Ni), a structure open to further chemistry. The next step involved reductive intercalation with Rb or Cs metal to form the air sensitive mixed-valence products with the nominal compositions, A1.5M0.5LaNb2O7. The last step involved the oxidative intercalation of chlorine using chlorine gas to obtain the final compounds. This multistep approach is a design to form mix-metal halide layers, specifically those with divalent cations, within layered perovskites, opening the doors to compounds that can have interesting properties. This reaction series was also applied to the tantalate layered oxides, leading to the formation of the new compound Ni 0.5LaTa2O7 through ion exchange. The further multistep topochemical manipulation of this new compound was not successful and was indicative of the difference in chemical behavior of the tantalates versus the niobates. We have also investigated the oxidative intercalation of halogens into a series of Ruddlesden-Popper (R-P) ruthenate oxides with the formula Ae n+1RunO3n+1 (Ae = Ca, Sr; n = 1, 2, 3) using several sources of fluorine, chlorine, and bromine. A new method was developed to intercalate chlorine into layered systems; this new approach avoids the use of chlorine gas which is highly toxic. The new phase Sr3Ru2O7Cl0.7 was synthesized by the new method and further topotactic manipulations were explored. The chemistry was not limited to the n = 2 phase but was also applied to the n = 3 phase, Sr4Ru3O10.

Chemistry

New Dion-Jacobson and Ruddlesden- Popper Layered Perovskites prepared by Topochemical Methods

Montasserasadi, Dariush

15 May 2015

Layered perovskites can be classified in three major groups: Dion-Jacobson AA′n-1BnO3n+1, Ruddlesden-Popper A2A′n-1BnO3n+1,and Aurivillius phase (Bi2O2)A′n-1BnO3n+1. (A: Alkali metal, Alkali-earth metal; A′: Lanthanides and Bi; B: Ti, Nb, Ta; n: thickness of slabs). For more than two decades researchers have shown much interest in this series because of their magnetic and electrical properties. Tuning synthesis parameters such as temperature, time, and host structure can be used to direct such properties. Low temperature synthetic methods (topochemical methods) allow the preparation of compounds not accessible by traditional high temperature reactions. This dissertation mainly considers the topochemical methods of ion exchange and reductive and oxidative intercalation to build new low temperature or metastable layered perovskites. The two-dimensional Dion-Jacobson ALaNb2O7 layered perovskites were intercalated reductively to produce A2LaNb2O7 andthen oxidized with water or hydro-chalcogenides (H2Ch, Ch: S, Se) to produce the novel alkali metal hydroxide, (A2OH)LaNb2O7, and alkali metal hydro-chalcogenides, (A2ChH)LaNb2O7, respectively. The synthesis and characterization of these compounds are presented in Chapters 2 and 3. In another set of studies, high temperature ceramic methods lead to the new host APrNb2O7. When this reaction is followed by ion exchange, (CuCl)PrNb2O7 can be prepared. The structural refinement, magnetic properties, and thermal stability of new phases have been studied in Chapter 4. The utility of praseodymium niobates for the formation of other metal oxyhalides was also developed; the series (MX)PrNb2O7 (M: Mn, Fe, Co, Cu and X: F, Cl) were prepared by the ion exchange of LiPrNb2O7 and the obtained phases characterized (Chapter 5). Further, to expand the library of materials and because of interesting properties of lanthanides (Ln: La, Pr, Nd, Sm), lanthanide tantalates have been explored for the preparation of oxyhalides and resulted in the compounds (CuCl)LnTa2O7 (Ln: Pr, Nd) (Chapter 6). Manipulation of Dion-Jacobson layered perovskites are not limited to lanthanides, other hosts with interesting properties have been examined (e.g. ABiNb2O7) (A: alkali metal, CuCl) and their crystal structures characterized along with thermal stability and magnetic response.

Layered perovskites

Topochemical methods

Ion exchange

Intercalation

Inorganic Chemistry

Materials Chemistry

"Desenvolvimento de interfaces eletroquímicas à base de nanocompósitos de poli(Pirrol) e xerogel lamelar de pentóxido de vanádio" / Development of electrochemical interfaces based on poly(pyrrole) and lamellar vanadium pentoxide xerogel nanocomposites.

Demets, Grégoire Jean-François

30 November 2001

Esta tese apresenta um estudo detalhado das propriedades eletroquímicas dos nanocompósitos de V2O5.nH2O e poli(pirrol) sobre a superfície de eletrodos. Demonstramos aqui que pelo controle de parâmetros de síntese é possível alterar a composição das interfaces eletroquímicas dos eletrodos modificados, fazendo com que o poli(pirrol) esteja por cima, por baixo ou dentro do V2O5 que recobre os eletrodos. Esta diferenciação estrutural tem repercussão nas propriedades eletroquímicas e espectroscópicas dos eletrodos modificados. Desenvolvemos além disto um método para gerar matrizes de V2O5.nH2O, assim como nanocompósitos com poli(pirrol) que possuam anisotropia elétrica tridimensional, propriedade útil em eletrônica. Na última parte do trabalho, poli(pirrol) foi inserido em matrizes de intercalação do tipo BV (V2O5.nH2O estabilizado com esmectita) gerando materiais estáveis em meio aquoso e adequados modificadores de eletrodos, viabilizando a exploração das propriedades dos compósitos de V2O5/poli(pirrol) em água. / This thesis focuses on the electrochemical properties of V2O5.nH2O and its poly(pyrrole) nanocomposites over electrodes. We demonstrate that it is possible, by controlling synthetic procedures, to change the composition of the modified electrodes interfaces, leaving poly(pyrrole) over, under or inside the V2O5 films covering the electrodes. This structural differenciation repercutes on the electrochemical and spectroscopic properties of the modified electrodes. We have developed also a method to generate V2O5.nH2O matrices as well as their nanocomposites with poly(pyrrole) showing tridimensional electrical anisotropy, a useful property in electronics. Additionally, poly(pyrrole) has been inserted into BV (smectite stabilized V2O5.nH2O) matrices, generating stable materials in aqueous medium, conveying to this, the properties of V2O5/poly(pyrrole) nanocomposites modified electrodes.

electrochemical interfaces

intercalation matrices

interfaces eletroquímicas

matrizes de intercalação

nanocomposites

nanocompósitos

pentóxido de vanádio

polipirrol

polypyrrole

vanadium pentoxide

"Desenvolvimento de interfaces eletroquímicas à base de nanocompósitos de poli(Pirrol) e xerogel lamelar de pentóxido de vanádio" / Development of electrochemical interfaces based on poly(pyrrole) and lamellar vanadium pentoxide xerogel nanocomposites.

Grégoire Jean-François Demets

30 November 2001

Esta tese apresenta um estudo detalhado das propriedades eletroquímicas dos nanocompósitos de V2O5.nH2O e poli(pirrol) sobre a superfície de eletrodos. Demonstramos aqui que pelo controle de parâmetros de síntese é possível alterar a composição das interfaces eletroquímicas dos eletrodos modificados, fazendo com que o poli(pirrol) esteja por cima, por baixo ou dentro do V2O5 que recobre os eletrodos. Esta diferenciação estrutural tem repercussão nas propriedades eletroquímicas e espectroscópicas dos eletrodos modificados. Desenvolvemos além disto um método para gerar matrizes de V2O5.nH2O, assim como nanocompósitos com poli(pirrol) que possuam anisotropia elétrica tridimensional, propriedade útil em eletrônica. Na última parte do trabalho, poli(pirrol) foi inserido em matrizes de intercalação do tipo BV (V2O5.nH2O estabilizado com esmectita) gerando materiais estáveis em meio aquoso e adequados modificadores de eletrodos, viabilizando a exploração das propriedades dos compósitos de V2O5/poli(pirrol) em água. / This thesis focuses on the electrochemical properties of V2O5.nH2O and its poly(pyrrole) nanocomposites over electrodes. We demonstrate that it is possible, by controlling synthetic procedures, to change the composition of the modified electrodes interfaces, leaving poly(pyrrole) over, under or inside the V2O5 films covering the electrodes. This structural differenciation repercutes on the electrochemical and spectroscopic properties of the modified electrodes. We have developed also a method to generate V2O5.nH2O matrices as well as their nanocomposites with poly(pyrrole) showing tridimensional electrical anisotropy, a useful property in electronics. Additionally, poly(pyrrole) has been inserted into BV (smectite stabilized V2O5.nH2O) matrices, generating stable materials in aqueous medium, conveying to this, the properties of V2O5/poly(pyrrole) nanocomposites modified electrodes.

interfaces eletroquímicas

matrizes de intercalação

nanocompósitos

pentóxido de vanádio

polipirrol

electrochemical interfaces

intercalation matrices

nanocomposites

polypyrrole

vanadium pentoxide

A Theoretical Study of Alkali Metal Intercalated Layered Metal Dichalcogenides and Chevrel Phase Molybdenum Chalcogenides

Kganyago, Khomotso R.

January 2004

Thesis (Ph.D. (Engineering mechanics)) --University of Limpopo, 2004 / This thesis explores the important issues associated with the insertion of Mg2+ and Li+ into the solid materials: molybdenum sulphide and titanium disulphide. This process, which is also known as intercalation, is driven by charge transfer and is the basic cell reaction of advanced batteries. We perform a systematic computational investigation of the new Chevrel phase, MgxMo6S8 for 0 ≤ x ≤ 2, a candidate for high energy density cathode in prototype rechargeable magnesium (Mg) battery systems. Mg2+ intercalation property of the Mo6S8 Chevrel phase compound and accompanied structural changes were evaluated. We conduct our study within the framework of both the local-density functional theory and the generalised gradient approximation techniques. Analysis of the calculated energetics for different magnesium positions and composition suggest a triclinic structure of MgxMo6S8 (x = 1 and 2). The results compare favourably with experimental data. Band-structure calculations imply the existence of an energy gap located ~1 eV above the Fermi level, which is a characteristic feature of the electronic structure of the Chevrel compounds. Calculations of electronic charge density suggest a charge transfer from Mg to the Mo6S8 cluster, which has a significant effect on the Mo-Mo bond length. There is relatively no theoretical work, in particular ab initio pseudopotential calculations, reported in literature on structural stability, cations "site energy" calculations, and pressure work. Structures obtained on the basis from experimental studies of other ternary molybdenum sulphides are examined with respect to pressure-induced structural transformation. We report the first bulk and linear moduli of the new Chevrel phase structures. This thesis also studies the reaction between lithium and titanium disulfide, which is the perfect intercalation reaction, with the product having the same structure over the range of reaction 0  x  1 in LixTiS2. Calculated lattice parameters, bulk moduli, linear moduli, elastic constants, density of states, and Mulliken populations are reported. Our calculations confirm that there is a single phase present with an expansion of the crystalline lattice as is typical for a solid solution, about 10% perpendicular to the basal plane layers. A slight expansion of the lattice in the basal plane is also observed due to the electron density increasing on the sulfur ions. Details on the correlation between the electronic structure and the energetic (i.e. the thermodynamics) of intercalation are obtained by establishing the connection between the charge transfer and lithium intercalation into TiS2. The theoretical determination of the densities of states for the pure TiS2 and Li1TiS2 confirms a charge transfer. Lithium charge is donated to the S (3p) and Ti (3d) orbitals. Comparison with experiment shows that the calculated optical properties for energies below 12 eV agrees well with reflectivity spectra. The structural and electronic properties of the intercalation compound LixTiS2, for x = 1/4, 3/4, and 1, are also investigated. This study indicates that the following physical changes in LixTiS2 are induced by intercalation: (1) the crystal expands uniaxially in the c-direction, (2) no staging is observed. We also focus on the intercalation voltage where the variation of the cell potential with the degree of discharge for LiTiS2 is calculated. Our results show that it can be predicted with these well-developed total energy methods. The detailed understanding of the electronic structure of the intercalation compounds provided by this method gives an approach to the interpretation of the voltage composition profiles of electrode materials, and may now clearly be used routinely to determine the contributions of the anode and cathode processes to the cell voltage. Hence becoming an important tool in the selection and design of new systems. Keywords Magnesium rechargeable battery; Chevrel, Lithium batteries; Li and Mg-ion insertion; TiS2; Mo6S8; Charge transfer; reflectivity, intercalation, elastic constants, voltage, EOS, Moduli. / the National Research Foundation, the Royal Society(U.K),the Council for Scientific and Industrial Research,and Eskom

Molybdenum Chalcogenides.

Magnesium rechargeable batteries

Intercalation

620.1893

Molybdenum

Batteries

Lithium cells

Preparation of Clay-dye pigment and its dispersion in polymers

Jamuna, Sivathasan, jsivathasan@yahoo.com

January 2008

This thesis is concerned with an experimental study of clay intercalation by organic dye molecule which is crucial for the successful development of a stable clay-dye pigment with combined advantages of organic dye and inorganic clay. Clay-dye pigments were prepared by two different methods. Two different organic dyes were used with unmodified clay and modified clay to study the intercalation. Characteristics of clay-dye pigment have been investigated using X-Ray Diffraction, Thermo-gravimetric Analysis and Transmission Electron Microscopy. In this thesis it is shown that the absorption of cationic dye by unmodified clay in aqueous medium mainly takes place in the interlayer clay surface. More likely the dye molecules with aromatic quaternary ammonium cation intercalate the clay layer and strongly interacts with the clay interlayer oxygen plane, where solvent dye (which is hydrophobic in nature) adsorption by unmodified clay mainly takes place on outer surface of the clay. Dye molecules are weakly interacted with outer surface oxygen plane by hydrogen bonding or Vander Waals forces. Modified clay enabled the solvent dye to intercalate inside the clay interlayer surface with the suitable non-aqueous medium (because of its expanded structure). The modified clay suspension in the selected non-aqueous medium shows only partial desorption of alkyl ammonium molecule from the clay layer with the presence of both cationic dye and solvent dye. Therefore the penetrated dye molecules must have weakly interacted with the interlayer oxygen plane as well as the remaining alkyl ammonium molecule present inside the clay layer. It is believed that the thermal and UV stability of organic dye can only be facilitated by a specific interaction (Ĉ-interactions) between aromatic alkyl ammonium cation of organic dye molecule and the interlayer oxygen plane of clay minerals. This interaction possibly enables the high thermal energy or the energy of the UV radiation to transmit immediately into the clay layer. Therefore organic dye molecules are protected from high energy loading and hence thermal and UV stability are improved.

Clay-dye pigments

clay intercalation

X-Ray Diffraction

oxygen plane

Ĉ-interactions

Développement de stratégies de gestion du combustible HTR

Guittonneau, Fabrice

28 October 2009

Dans un souci de réduction du volume de déchets nucléaires et de revalorisation des matières combustibles, une stratégie de gestion du combustible des réacteurs à haute température (HTR) est développée dans cette étude. La réduction de volume passe par la séparation des particules TRISO hautement radioactives et du graphite faiblement radioactif (les deux étant réunis dans un assemblage de combustible appelé "compact") tandis que le recyclage total nécessite la séparation du coeur de la particule, valorisable, et de sa gangue, déchet ultime. Les méthodes de séparation doivent préserver l'intégrité des TRISO afin d'empêcher la fuite des radioéléments. Ainsi, le traitement de choc thermique entre l'azote liquide et l'eau chaude permet une division partielle des compacts mais ne permet de récupérer que peu de particules. L'érosion du graphite par jet d'eau à haute pression présente le risque de fracturer les particules. La combustion totale du carbone libère toutes les billes. Le traitement des compacts par les ultrasons dans l'eau érode le graphite en fonction de l'intensité de travail, des direction et distance d'attaque, de la température et du gaz de saturation, nettoyant les particules. L'attaque acide des compacts par un mélange H2O2 + H2SO4 provoque l'intercalation du graphite par l'acide, faisant gonfler la structure et libérant ainsi les billes intactes. Les TRISO d'une part et leurs gangues d'autre part ont ensuite été vitrifiées par frittage de manière à obtenir une forte densité, jusqu'à un taux de 25% vol. Enfin, la lixiviation des composites dans l'eau ultrapure à 90°C montre de fortes propriétés de confinement.

HTR

gestion du combustible

particule TRISO

graphite

ultrasons

intercalation/exfoliation

vitrification

lixiviation