Understanding Ionic Conductivity in Crystalline Polymer Electrolytes

Brandell, Daniel

January 2005

Polymer electrolytes are widely used as ion transport media in vital applications such as energy storage devices and electrochemical displays. To further develop these materials, it is important to understand their ionic conductivity mechanisms. It has long been thought that ionic conduction in a polymer electrolyte occurs in the amorphous phase, while the crystalline phase is insulating. However, this picture has recently been challenged by the discovery of the crystalline system LiXF6∙PEO6 (X=P, As or Sb) which exhibits higher conductivity than its amorphous counterpart. Their structures comprise interlocking hemi-helical PEO-chain pairs containing Li+ ions and separating them from the XF6- anions. The first Molecular Dynamics (MD) simulation study of the LiPF6∙PEO6 system is presented in this thesis. Although its conductivity is too low for most applications at ambient temperature, it can be enhanced by iso- and aliovalent anion doping. It is shown that the diffraction-determined structure is well reproduced on simulating the system using an infinite PEO-chain model. The Li-Oet coordination number here becomes 6 instead of 5; minor changes also occur in the polymer backbone configuration. The crystallographic asymmetric unit and diffraction profiles are also reproduced. On simulating a shorter-chain system (n=22), more resembling the real material, the structure retains its double hemi-helices, but the polymer adopts a more relaxed conformation, facilitating the formation of Li+-PF6- pairs. Infinite-chain simulation shows the ionic conduction to be dominated by anion motion, in contrast to earlier NMR results. The effects of doping are also reproduced. Shortening the polymer chain-length has the effect of raising the transport number for lithium, thereby bring it into better agreement with experiment. It can be concluded that it is critical to take polymer chain-length and chain-termination into account when modelling ionic conductivity mechanisms in crystalline polymer electrolytes.

Chemistry

Polymer electrolyte

molecular dynamics

conductivity mechanism

aliovalent anion substitution

smectic

nematic

polymer chain length

Kemi

Chemistry

Kemi

The Application of Weak-Anion Exchange Chromatography for the Analysis of Organic Zwitterions Using LC/MS/MS

Bishop, Michael Jason

04 December 2006

A rapid and accurate quantitative method was developed and validated for the analysis of four urinary organic acids with nitrogen containing functional groups, formiminoglutamic acid (FIGLU), pyroglutamic acid (PYRGLU), 5-hydroxyindoleacetic acid (5-HIAA), and 2-methylhippuric acid (2-METHIP) by liquid chromatography tandem mass spectrometry (LC/MS/MS). The chromatography was developed using a weak anion-exchange amino column that provided mixed-mode retention of the analytes. The elution gradient relied on changes in mobile phase pH over a concave gradient, without the use of counter-ions or concentrated salt buffers. A simple sample preparation was used, only requiring the dilution of urine prior to instrumental analysis. The method was validated based on linearity (r2 ¡Ý 0.995), accuracy (85¨C115%), precision (C.V. < 12%), sample preparation stability (¡Ü 5%, 72h), and established patient ranges. The method was found to be both efficient and accurate for the analysis of urinary zwitterionic organic acids.

Weak anion exchange

Formiminoglutamic acid

Pyroglutamic acid

5-Hydroxyindoleacetic acid

2-Methylhippuric acid

LC/MS/MS

Organic acids

Addition Of Acyl Phosphonates To Ethylcyanoformate

Reis, Barbaros

01 December 2007

Functionalized cyanophosphates are important starting materials for the synthesis of beta-lactam ring moiety of beta-lactam antibiotics. The cyanophosphates are synthesized starting from easily available acylphosphonate and ethylcyanoformate. Acylphosphonates are synthesized starting from acylchloride and trimethylphosphite. Addition of acylphoshonate to ethylcyanoformate furnishes the cyanophosphate with the quaternary center.

QD Organic Chemistry 241-441

The importance of charged amino acids in the human Organic Anion Transporter 1 / Die funktionelle Bedeutung geladener Aminosäurereste im humanen Organische-Anionen-Transporter 1

Rizwan, Ahsan Naqi

16 January 2007

No description available.

500 Naturwissenschaften allgemein

Mathematics and Computer Science

Organische-Anionen-Transporter

Mutagenese

Chlorid

organic anion transporter

mutagenesis

chloride

42

Wa 000

Differential Roles of Tryptophan Residues in the Functional Expression of Human Anion Exchanger 1

Okawa, Yuka

15 August 2012

Anion exchanger 1 (AE1) is a 95 kDa glycoprotein that facilitates Cl-/HCO3- exchange across the erythrocyte plasma membrane. Seven conserved tryptophan (Trp) residues are in the AE1 membrane domain; at the membrane interface (Trp648, Trp662, and Trp723), in transmembrane segment (TM) 4 (Trp492 and Trp496), and in hydrophilic loops (Trp831, and Trp848). All 7 Trp residues were individually mutated into alanine (Ala) and phenylalanine (Phe) and transiently expressed in human embryonic kidney (HEK)-293 cells. The 7 Trp residues could be grouped into three classes according to the impact of the mutations on the functional expression of AE1: class 1, normal expression, class 2, expression decreased, and class 3, expression decreased by Ala substitution. These results indicate that Trp residues play differential roles in AE1 expression depending on their location in the protein and suggest that Trp mutants with a low expression are misfolded and retained in the ER.

Anion exchanger 1

Membrane protein

Tryptophan

Protein expression

Protein function

Trafficking

Cell surface expression

N-glycosylation

0487

0379

Molecular Characterization of Hereditary Spherocytosis Mutants of the Cytoplasmic Domain of Anion Exchanger 1 and their Interaction with Protein 4.2

Bustos, Susan

29 August 2011

Anion exchanger 1 (AE1) is a red cell membrane glycoprotein that associates with cytoskeletal protein 4.2 in a complex bridging the cell membrane to the cytoskeleton. Disruption of this linkage results in unstable erythrocytes and hereditary spherocytosis (HS). Three HS mutations (E40K, G130R and P327R) in the cytoplasmic domain of AE1 (cdAE1) result in a decreased level of protein 4.2 in the red cell yet maintain normal amounts of AE1. Biophysical analyses showed the HS mutations had little effect on the structure and conformational stability of the isolated domain. However, the conformation of the cytoplasmic domain of the kidney anion exchanger, lacking the first 65 amino acids including a central -strand, was thermally destabilized relative to cdAE1 and had a more open structure. In transfected human embryonic kidney (HEK)-293 cells the HS mutants had similar expression levels as wild-type AE1, and protein 4.2 expression level was not dependent on the presence of AE1. Protein 4.2 localized to the plasma membrane with wild-type AE1, the HS mutants of AE1, the membrane domain of AE1 and kidney AE1, and to the ER with Southeast Asian ovalocytosis AE1. A fatty acylation mutant of protein 4.2, G2A/C173A, could not localize to the plasma membrane in the absence of AE1. Subcellular fractionation showed wild-type and G2A/C173A protein 4.2 were mostly associated with the cytoskeleton. Co-immunoprecipitation and Ni-NTA pull-down assays revealed impaired binding of protein 4.2 to HS mutants compared to AE1, while the membrane domain of AE1 was unable to bind protein 4.2. These studies show that HS mutations in cdAE1 cause impaired binding of protein 4.2, without causing gross structural changes in the domain. The mutations change the binding surface on cdAE1 by the introduction of positive charges into an otherwise acidic domain. This binding impairment may render protein 4.2 more susceptible to degradation or loss during red cell development.

anion exchanger 1

protein 4.2

erythrocyte

cytoskeleton

protein-protein interactions

protein structure and stability

red blood cell

0487

Differential Roles of Tryptophan Residues in the Functional Expression of Human Anion Exchanger 1

Okawa, Yuka

15 August 2012

Anion exchanger 1 (AE1) is a 95 kDa glycoprotein that facilitates Cl-/HCO3- exchange across the erythrocyte plasma membrane. Seven conserved tryptophan (Trp) residues are in the AE1 membrane domain; at the membrane interface (Trp648, Trp662, and Trp723), in transmembrane segment (TM) 4 (Trp492 and Trp496), and in hydrophilic loops (Trp831, and Trp848). All 7 Trp residues were individually mutated into alanine (Ala) and phenylalanine (Phe) and transiently expressed in human embryonic kidney (HEK)-293 cells. The 7 Trp residues could be grouped into three classes according to the impact of the mutations on the functional expression of AE1: class 1, normal expression, class 2, expression decreased, and class 3, expression decreased by Ala substitution. These results indicate that Trp residues play differential roles in AE1 expression depending on their location in the protein and suggest that Trp mutants with a low expression are misfolded and retained in the ER.

Anion exchanger 1

Membrane protein

Tryptophan

Protein expression

Protein function

Trafficking

Cell surface expression

N-glycosylation

0487

0379

Molecular Characterization of Hereditary Spherocytosis Mutants of the Cytoplasmic Domain of Anion Exchanger 1 and their Interaction with Protein 4.2

Bustos, Susan

29 August 2011

Anion exchanger 1 (AE1) is a red cell membrane glycoprotein that associates with cytoskeletal protein 4.2 in a complex bridging the cell membrane to the cytoskeleton. Disruption of this linkage results in unstable erythrocytes and hereditary spherocytosis (HS). Three HS mutations (E40K, G130R and P327R) in the cytoplasmic domain of AE1 (cdAE1) result in a decreased level of protein 4.2 in the red cell yet maintain normal amounts of AE1. Biophysical analyses showed the HS mutations had little effect on the structure and conformational stability of the isolated domain. However, the conformation of the cytoplasmic domain of the kidney anion exchanger, lacking the first 65 amino acids including a central -strand, was thermally destabilized relative to cdAE1 and had a more open structure. In transfected human embryonic kidney (HEK)-293 cells the HS mutants had similar expression levels as wild-type AE1, and protein 4.2 expression level was not dependent on the presence of AE1. Protein 4.2 localized to the plasma membrane with wild-type AE1, the HS mutants of AE1, the membrane domain of AE1 and kidney AE1, and to the ER with Southeast Asian ovalocytosis AE1. A fatty acylation mutant of protein 4.2, G2A/C173A, could not localize to the plasma membrane in the absence of AE1. Subcellular fractionation showed wild-type and G2A/C173A protein 4.2 were mostly associated with the cytoskeleton. Co-immunoprecipitation and Ni-NTA pull-down assays revealed impaired binding of protein 4.2 to HS mutants compared to AE1, while the membrane domain of AE1 was unable to bind protein 4.2. These studies show that HS mutations in cdAE1 cause impaired binding of protein 4.2, without causing gross structural changes in the domain. The mutations change the binding surface on cdAE1 by the introduction of positive charges into an otherwise acidic domain. This binding impairment may render protein 4.2 more susceptible to degradation or loss during red cell development.

anion exchanger 1

protein 4.2

erythrocyte

cytoskeleton

protein-protein interactions

protein structure and stability

red blood cell

0487

Involvement of Membrane Transport Proteins in Intestinal Absorption and Hepatic Disposition of Drugs Using Fexofenadine as a Model Drug

Petri, Niclas

January 2005

The aims of this thesis were to study the in vivo relevance of membrane transporters for intestinal absorption and the hepatic disposition of drugs in humans and preclinical models. Fexofenadine is a substrate for ABCB1 (P-glycoprotein) and members of the organic anion transporting polypeptide (OATP/SLCO) family. It is marginally metabolised in humans. The influence of known inhibitors of ABCB1 and OATPs on the membrane transport and pharmacokinetics of fexofenadine was investigated in Caco-2 and porcine models and in humans. The permeability of fexofenadine remained low, even when significantly altered by the addition of an inhibitor. Using the Loc-I-Gut® technique in vivo in humans, it was possible to see that the jejunal effective permeability of fexofenadine was unchanged when given with verapamil. However, the systemic exposure and apparent absorption rate of fexofenadine increased. This suggests that the first-pass liver extraction of fexofenadine was reduced by verapamil, probably through the inhibition of sinusoidal OATP-mediated and/or canalicular ABCB1-mediated secretion. The unchanged permeability can be explained by simultaneous inhibition of jejunal apical OATP-uptake and ABCB1-efflux, which would leave fexofenadine to be transported by passive trancellular diffusion. A Loc-I-Gut® perfusion in the porcine model enabling blood sampling in the portal and hepatic veins and bile collection revealed increased jejunal permeability, but no subsequent verapamil-induced elevation in the systemic exposure of fexofenadine. This indicates a species-related difference in the localisation of and/or the substrate specificity of fexofenadine for the transporters involved. The absence of an effect on the first-pass liver extraction in the porcine model might be caused by the observed lower liver exposure of verapamil. Finally, a novel intubation technique enabling dosing of fexofenadine in the jejunum, ileum and the colon showed that fexofenadine was absorbed less along the length the intestine in agreement with the properties of a low permeability drug.

Biopharmacy

Fexofenadine

OATP

P-glycoprotein

Organic Anion Transporters

ATP-Binding Cassette Transporters

membrane transport proteins

Bioavailability

Biopharmaceutics

Biofarmaci

Biopharmacy

Biofarmaci

Redução de oxigênio molecular em soluções aquosas através da metodologia de modificação de eletrodos / Reduction of molecular oxygen in aqueous solutions through modifying electrodes\' methodology

Nara Alexiou Zacarias

27 September 2007

Este trabalho consistiu de estudos da viabilidade da geração e identificação de radicais livres envolvidos em processos oxidativos avançados por via eletroquímica. Para a geração e identificação de radicais livres em eletrodos modificados com organotióis via eletroquímica, escolheu-se uma técnica pouco aplicada para este fim; a espectroscopia de impedância eletroquímica, e o ajuste dos dados experimentais pela proposta de modelos de circuitos equivalentes. O eletrodo de trabalho utilizado (Au) foi caracterizado em meio ácido e básico e diversas monocamadas auto-organizadas conhecidas foram adsorvidas sobre o mesmo e também caracterizadas por esta técnica. Parâmetros importantes como constante dielétrica, capacitância de uma monocamada livre de defeitos e grau de recobrimento foram determinados com êxito. Também foram empregadas moléculas menos utilizadas como modificadoras de eletrodos (fenotiazinas e derivados). As mesmas foram caracterizadas no sistema Au/adsorvente/NaOH, pois, o pH alto garante a formação do radical superóxido e do ânion hidroperóxido. Os mesmos modelos de circuitos equivalentes puderam ser empregados na obtenção dos parâmetros físicos relativos a essas moléculas no sistema eletroquímico utilizado. Em uma etapa subsequente obteve-se a valiosa informação, se as moléculas adsorvidas sobre Au poderiam ser usadas para a geração de superóxido e outros radicais. As monocamadas de tióis, quando utilizadas para gerar radicais livres, se mostraram aptas a gerar superóxido em meio alcalino saturado com oxigênio molecular. Como se demonstrou na etapa de caracterização, as SAM-3 e SAM-6 não formaram um empacotamento totalmente hidrofóbico. Por este motivo, mesmo que superóxido tenha sido gerado, não pôde ser detectado. Já para a fenotiazina e seu metil-derivado, a cinética de adsorção e a utilização de soluções aquosas impediram a formação de um filme completo e homogêneo, imprescindível para a constituição de uma interface hidrofóbica e isolante. Além disso, possíveis reações de complexação entre as moléculas e superóxido, reações entre a fenotiazina cátion-radical e superóxido fazem necessários mais estudos acerca da natureza eletroquímica do sistema, que já é bastante conhecido fotoquimicamente. Posterior a modificação, todos os eletrodos se mostraram ser bastante sensíveis ao pH e aos eletrólitos utlizados, alterando-se a estrutura interna muito facilmente, o qual implica uma limitação no tempo de uso e reprodutibilidade quando da geração de um radical tão reativo quanto superóxido. / This work consisted in testing the viability of investigations into the electrochemical generation and identification of free radicals involved in advanced oxidative processes. In these studies, a technique which is rarely used for the electrochemical generation and identification of free radicals at organothiole-modified electrodes, electrochemical impedancy spectroscopy, was chosen and the experimental data obtained were fitted by equivalent circuit models. A working electrode (Au) was characterized in both acidic and basic media and several known self-assembled monolayers were adsorbed over this electrode and also characterized using this technique. Important parameters such as dielectric constants, capacitance of the monolayers free of defects and coverage were determined with success. Other lesser-known molecules such as phenothiazines and their derivatives were also used .The modified electrodes were characterized in NaOH solution, since the high pH assures the production of superoxide radicals and hydroperoxylate anions. The equivalent circuit model was employed to obtain physical parameters for these molecules in the electrochemical systems studied. In a subsequent step, a valuable piece of information was obtained; it was noted that the molecules adsorbed over Au could be used in order to generate superoxide and other radicals. The ability of thiol monolayers used in the generation of free radicals, to produce superoxides in alkaline media saturated with molecular oxygen was demonstrated. However, characterization of the self-assembled monolayers, SAM-3 and SAM-6, revealed that these were not able to pack in a completely hydrophobic manner. This may account for the fact that the superoxide could not be detected even when it was believed to have formed. For the phenothiazine-modified electrodes, the adsorption kinetics and the utilization of aqueous solutions prevented the formation of an intact and homogeneous film, which is essential in establishing a hydrophobic and isolating interface. Furthermore, possible complexation reactions between the molecules and the superoxide and reactions between the phenothiazine cation-radical and superoxide, point to the need for further studies regarding the electrochemical nature of this system, whose photochemical properties are very well known. Following modification, all the electrodes were shown to be too sensitive to pH and to the electrolytes used, since the inner structure was easily modified, which implies that they would have a limited time of use and in addition that the reproducibility of the rate of generation of reactive radical species such as superoxides could be compromised.

Ânion-radical

Modificação eletroquímica

Monocamadas auto-organizadas

Sensores

Superóxido

Tióis

Electrochemical modification

Radical anion

Self-assembled monolayers

Sensors

Superoxide

Thiols