Global ETD Search

411	Dinâmica Molecular de Peptídeos na Interface Membrana-Água / Molecular dynamics of peptides in the membrane-water interface Pascutti, Pedro Geraldo 25 October 1996 (has links) Um programa computacional foi desenvolvido para otimização de geometria e simulação de dinâmica molecular baseado em um campo de forças clássicas parametrizado. O solvente foi considerado como um contínuo eletrostático e a interface entre o meio aquoso e o interior de uma membrana biológica como uma superfície de descontinuidade dielétrica, tratada pelo \"método das imagens eletrostáticas\". Nesse método, o campo de polarização produzido na superfície de descontinuidade por uma carga pontual é representado por uma carga fictícia, colocada na fase oposta, cuja distância e sinal é definida pelas condições de contorno na superfície. Diversos sistemas foram estudados, tanto em solventes contínuos como na presença de superfícies de descontinuidade: a) Foram estudadas as distribuições populacionais dos rotâmeros do triptofano na forma zwitteriônica e no peptídeo Ala-Trp- Ala, em solvente polar e apolar. Foi demonstrado que a dinâmica do triptofano e as populações de rotâmeros são compatíveis com as observações experimentais de fluorescência resolvida no tempo e NMR; b) Em um estudo das conformações em polialanina, verificou-se que a estabilidade da estrutura secundária hélice- é um efeito cooperativo entre pontes de hidrogênio em solvente de baixa constante dielétrica. Na presença da interface água-membrana, a hélice- anfifílica de um modelo para a -endorfina estabiliza-se sobre a interface. Um comportamento anfifílico foi também observado na seqüência sinal para o receptor- da e. coli, a qual estabilizou-se perpendicularmente à interface, na conformação parcial hélice- proposta na literatura; c) Em um estudo sobre o hormônio -MSH observou-se que, em solvente polar, de uma conformação helicoidal ele passa para uma conformação estendida. Porém, ao atravessar para o interior hidrofóbico de uma membrana, o peptídeo estabiliza-se em dobra-. Observou-se ainda que a estabilidade dessa conformação no interior da membrana é reforçada por pontes salinas entre os resíduos carregados do peptídeo, os quais formam um \"caroço\" hidrofílico circundado por resíduos hidrofóbicos. Esse arranjo estrutural está em concordância com o proposto para a conformação biologicamente ativa. De um modo geral, o modelo para biomembrana proposto no presente trabalho reproduziu o comportamento hidrofóbico, hidrofílico ou anfifílico dos peptídeos estudados. / A software was developed for optimisation of geometry and molecular dynamics simulation, based on a parameterized classical force field. Solvent was assumed as an electrostatic continuum. The interface between the aqueous medium and the hydrophobic core of biological membranes was described by a surface of dielectric discontinuity, treated by the \"method of images\". In this method, the polarization field produced at the surface of discontinuity by a point charge was represented by a fictitious charge, placed in the opposite phase. The position and signal of this charge-image were defined by boundary conditions at the surface. Several systems were studied, either in continuous solvent, as in the presence of discontinuity surfaces: a) the population distribution of tryptophan rotamers was studied in the zwytterion and in the peptide Ala-Trp-Ala, in polar and apolar solvents; the results for the tryptophan dynamics and the rotamers populations agree with experimental observations using time resolved fluorescence and NMR spectroscopies. b) analysis of polyalanin conformations showed that the stabililty of the -helix is a cooperative effect between hydrogen bonds in low dielectric constant solvent; in the presence of the water-membrane interface, the amphyphilic -helix of a -endorphin model stabilizes on the interface; a similar behavior was observed in the signal sequence for the E. Coli -receptor, that stabilized perpendicular to the interface in a partial -helix conformation, as proposed in the literature. c) calculations on melanotropic hormone a.-MSH showed that in polar solvent it goes from helycoidal conformation to an extended one; in the presence of the interface water-membrane, the peptide goes into the interior of the membrane and stabilizes in a -turn; the stability ofthis conformation was reinforced by salt bridges between charged residues, forming a hydrophilic core surrounded by hydrophobic residues; this structural arrangement agrees with the one proposed for the biologically active conformation of the hormone. In general terms, the model proposed here for the biomembrane was able to mimic the hydrophobic, hydrophihlic or amphyphilic behavior of the peptides studied. Cell membranes Dinâmica molecular Electrostatic images Estruturas secundárias Fluorescence Fluorescência Fluorescência do triptofano Imagens eletrostáticas Membranas celulares Molecular dynamics Peptídeos Peptides Secondary structures Tryptophan fluorescence
412	Ghosts and bottlenecks in elastic snap-through Gomez, Michael January 2018 (has links) Snap-through is a striking instability in which an elastic object rapidly jumps from one state to another. It is seen in the leaves of the Venus flytrap plant and umbrellas flipping on a windy day among many other examples. Similar structures that snap-through are used to generate fast motions in soft robotics, switches in micro-scale electronics and artificial heart valves. Despite the ubiquity of snap-through in nature and engineering, its dynamics is usually only understood qualitatively. In this thesis we develop analytical understanding of this dynamics, focussing on how the mathematical structure underlying the snap-through transition controls the timescale of instability. We begin by considering the dynamics of 'pull-in' instabilities in microelectromechanical systems (MEMS) - a type of snap-through caused by electrostatic forces in which the motions are dominated by fluid damping. Using a lumped-parameter model, we show that the observed time delay near the pull-in transition is a type of critical slowing down - a so-called 'bottleneck' due to the 'ghost' of a saddle-node bifurcation. We obtain a scaling law describing this slowing down, and, in the process, unify a large range of experiments and simulations that exhibit delay phenomena during pull-in. We also investigate the pull-in dynamics of MEMS microbeams, extending the lumped-parameter approach to incorporate the details of the beam geometry. This provides a model system in which to understand snap-through of a continuous elastic structure due to external loading. We develop a perturbation method that systematically exploits the proximity to pull-in to reduce the governing equations to a simpler evolution equation, with a structure that highlights the saddle-node bifurcation. This allows us to analyse the bottleneck dynamics in detail, which we compare with previous experimental and numerical data. The remainder of the thesis is concerned with the dynamics of snap-through in macroscopic systems. In particular, we explore the extent to which dissipation is required to explain anomalously slow snap-through. Considering an elastic arch as an archetype of a snapping system, we use the perturbation method developed earlier to show that two bottleneck regimes are possible, depending delicately on the relative importance of external damping. In particular, we show that critical slowing down occurs even in the absence of damping, leading to a new scaling law for the snap-through time that is confirmed by elastica simulations and experiments. In many real systems material viscoelasticity is present to some degree. Finally, we examine how this influences the snap-through dynamics of a simple truss-like structure. We present a regime diagram that characterises when the timescale of snap-through is controlled by viscous, elastic or viscoelastic effects. 510
413	Dinâmica Molecular de Peptídeos na Interface Membrana-Água / Molecular dynamics of peptides in the membrane-water interface Pedro Geraldo Pascutti 25 October 1996 (has links) Um programa computacional foi desenvolvido para otimização de geometria e simulação de dinâmica molecular baseado em um campo de forças clássicas parametrizado. O solvente foi considerado como um contínuo eletrostático e a interface entre o meio aquoso e o interior de uma membrana biológica como uma superfície de descontinuidade dielétrica, tratada pelo \"método das imagens eletrostáticas\". Nesse método, o campo de polarização produzido na superfície de descontinuidade por uma carga pontual é representado por uma carga fictícia, colocada na fase oposta, cuja distância e sinal é definida pelas condições de contorno na superfície. Diversos sistemas foram estudados, tanto em solventes contínuos como na presença de superfícies de descontinuidade: a) Foram estudadas as distribuições populacionais dos rotâmeros do triptofano na forma zwitteriônica e no peptídeo Ala-Trp- Ala, em solvente polar e apolar. Foi demonstrado que a dinâmica do triptofano e as populações de rotâmeros são compatíveis com as observações experimentais de fluorescência resolvida no tempo e NMR; b) Em um estudo das conformações em polialanina, verificou-se que a estabilidade da estrutura secundária hélice- é um efeito cooperativo entre pontes de hidrogênio em solvente de baixa constante dielétrica. Na presença da interface água-membrana, a hélice- anfifílica de um modelo para a -endorfina estabiliza-se sobre a interface. Um comportamento anfifílico foi também observado na seqüência sinal para o receptor- da e. coli, a qual estabilizou-se perpendicularmente à interface, na conformação parcial hélice- proposta na literatura; c) Em um estudo sobre o hormônio -MSH observou-se que, em solvente polar, de uma conformação helicoidal ele passa para uma conformação estendida. Porém, ao atravessar para o interior hidrofóbico de uma membrana, o peptídeo estabiliza-se em dobra-. Observou-se ainda que a estabilidade dessa conformação no interior da membrana é reforçada por pontes salinas entre os resíduos carregados do peptídeo, os quais formam um \"caroço\" hidrofílico circundado por resíduos hidrofóbicos. Esse arranjo estrutural está em concordância com o proposto para a conformação biologicamente ativa. De um modo geral, o modelo para biomembrana proposto no presente trabalho reproduziu o comportamento hidrofóbico, hidrofílico ou anfifílico dos peptídeos estudados. / A software was developed for optimisation of geometry and molecular dynamics simulation, based on a parameterized classical force field. Solvent was assumed as an electrostatic continuum. The interface between the aqueous medium and the hydrophobic core of biological membranes was described by a surface of dielectric discontinuity, treated by the \"method of images\". In this method, the polarization field produced at the surface of discontinuity by a point charge was represented by a fictitious charge, placed in the opposite phase. The position and signal of this charge-image were defined by boundary conditions at the surface. Several systems were studied, either in continuous solvent, as in the presence of discontinuity surfaces: a) the population distribution of tryptophan rotamers was studied in the zwytterion and in the peptide Ala-Trp-Ala, in polar and apolar solvents; the results for the tryptophan dynamics and the rotamers populations agree with experimental observations using time resolved fluorescence and NMR spectroscopies. b) analysis of polyalanin conformations showed that the stabililty of the -helix is a cooperative effect between hydrogen bonds in low dielectric constant solvent; in the presence of the water-membrane interface, the amphyphilic -helix of a -endorphin model stabilizes on the interface; a similar behavior was observed in the signal sequence for the E. Coli -receptor, that stabilized perpendicular to the interface in a partial -helix conformation, as proposed in the literature. c) calculations on melanotropic hormone a.-MSH showed that in polar solvent it goes from helycoidal conformation to an extended one; in the presence of the interface water-membrane, the peptide goes into the interior of the membrane and stabilizes in a -turn; the stability ofthis conformation was reinforced by salt bridges between charged residues, forming a hydrophilic core surrounded by hydrophobic residues; this structural arrangement agrees with the one proposed for the biologically active conformation of the hormone. In general terms, the model proposed here for the biomembrane was able to mimic the hydrophobic, hydrophihlic or amphyphilic behavior of the peptides studied. Dinâmica molecular Estruturas secundárias Fluorescência Fluorescência do triptofano Imagens eletrostáticas Membranas celulares Peptídeos Cell membranes Electrostatic images Fluorescence Molecular dynamics Peptides Secondary structures Tryptophan fluorescence
414	Hybrid Electrochemical Capacitors: Materials, Optimization, and Miniaturization Agrawal, Richa 11 January 2018 (has links) With the ever-advancing technology, there is an incessant need for reliable electrochemical energy storage (EES) components that can provide desired energy and power. At the forefront of EES systems are electrochemical capacitors (ECs), also known as supercapacitors that typically have higher power and superior cycle longevity but lower energy densities than their battery counterparts. One of the routes to achieve higher energy density for ECs is using the hybrid EC configuration, which typically utilizes a redox electrode coupled with a counter double-layer type electrode. In this dissertation, both scale-up (coin-cell type) as well as scale-down (on-chip miniaturized) hybrid ECs were designed, constructed and evaluated. The first part of the dissertation comprised material identification, syntheses, and electrochemical analyses. Lithium titanate-anatase titanium oxide (Li4Ti5O12-TiO2) composites were synthesized via electrostatic spray deposition (ESD) and characterized in both half-cell and full-cell assembly against lithium and nanostructured carbon based counter electrodes, respectively. The second redox type material studied for hybrid electrochemical capacitors was ESD derived manganese oxide (MnOx). The MnOx electrodes exhibited a high gravimetric capacitance of 225F g-1 in aqueous media. Further improvement in the rate handling of the MnOx electrodes was achieved by using CNT additives. The MnOx-CNT composites were tested in full-cell assembly against activated carbon counter electrodes and tested for different anode and cathode mass ratios in order to achieve the best energy-power tradeoff, which was the second major goal of the dissertation. The optimized hybrid capacitor was able to deliver a high specific energy density of 30.3 Wh kg-1 and a maximal power density of 4kW kg-1. The last part of the dissertation focused on a scale-down miniaturized hybrid microsupercapacitor; an interdigitated electrode design was adopted in order to shorten the ion-transport pathway, and MnOx and reduced graphene oxide (rGO) were chosen as the redox and double layer components, respectively. The hybrid microsupercapacitor was able to deliver a high stack energy density of 1.02 mWh cm-3 and a maximal stack power density of 3.44 W cm-3, both of which are comparable with thin-film batteries and commercial supercapacitor in terms of volumetric energy and power densities. Supercapacitors Lithium-ion capacitors Manganese oxide Electrostatic Spray Deposition (ESD) Carbon MEMS Microfabrication Nanostructured carbons Lithium titanate Materials Chemistry Materials Science and Engineering Nanoscience and Nanotechnology Physical Chemistry
415	The birth and growth of the protein folding nucleus : Studies of protein folding focused on critical contacts, topology and ionic interactions Hedberg, Linda January 2008 (has links) <p>Proteins are among the most complex molecules in the cell and they play a major role in life itself. The complexity is not restricted to just structure and function, but also embraces the protein folding reaction. Within the field of protein folding, the focus of this thesis is on the features of the folding transition state in terms of growing contacts, common nucleation motifs and the contribution of charged residues to stability and folding kinetics. </p><p>During the resent decade, the importance of a certain residue in structure formation has been deduced from Φ-value analysis. As a complement to Φ-value analysis, I present how scatter in a Hammond plot is related to site-specific information of contact formation, Φ´(β<sup>TS</sup>), and this new formalism was experimentally tested on the protein L23. The results show that the contacts with highest Φ growth at the barrier top were distributed like a second layer outside the folding nucleus. This contact layer is the critical interactions needed to be formed to overcome the entropic barrier. </p><p>Furthermore, the nature of the folding nucleus has been shown to be very similar among proteins with homologous structures and, in the split β-α-β family the proteins favour a two-strand-helix motif. Here I show that the two-strand-helix motif is also present in the ribosomal protein S6 from<i> A. aeolicus</i> even though the nucleation and core composition of this protein differ from other related structure-homologues. </p><p>In contrast to nucleation and contact growth, which are events driven by the hydrophobic effect, my most recent work is focused on electrostatic effects. By pH titration and protein engineering the charge content of S6 from <i>T. thermophilus</i> was altered and the results show that the charged groups at the protein surface might not be crucial for protein stability but, indeed, have impact on folding kinetics. Furthermore, by site-specific removal of all acidic groups the entire pH dependence of protein stability was depleted.</p> protein folding protein stability two-state folding chevron plot transition-state movements Hammond behaviour topology electrostatic interactions pH dependence mass-action protein engineering pKa Biochemistry Biokemi
416	Drug Partitioning into Natural and Artificial Membranes : Data Applicable in Predictions of Drug Absorption Engvall, Caroline January 2005 (has links) <p>When drug molecules are passively absorbed through the cell membrane in the small intestine, the first key step is partitioning of the drug into the membrane. Partition data can therefore be used to predict drug absorption. The partitioning of a solute can be analyzed by drug partition chromatography on immobilized model membranes, where the chromatographic retention of the solute reflects the partitioning. The aims of this thesis were to develop the model membranes used in drug partition chromatography and to study the effects of different membrane components and membrane structures on drug partitioning, in order to characterize drug–membrane interactions.</p><p>Electrostatic effects were observed on the partitioning of charged drugs into liposomes containing charged detergent, lipid or phospholipid; bilayer disks; proteoliposomes and porcine intestinal brush border membrane vesicles (BBMVs), and on the retention of an oligonucleotide on positive liposomes. Biological membranes are naturally charged, which will affect drug partitioning in the human body.</p><p>Proteoliposomes containing transmembrane proteins and cholesterol, BBMVs and bilayer disks were used as novel model membranes in drug partition chromatography. Partition data obtained on proteoliposomes and BBMVs demonstrated how cholesterol and transmembrane proteins interact with drug molecules. Such interactions will occur between drugs and natural cell membranes. In the use of immobilized BBMVs for drug partition chromatography, yet unsolved problems with the stability of the membrane were encountered. A comparison of partition data obtained on bilayer disks with data on multi- and unilamellar liposomes indicated that the structure of the membrane affect the partitioning. The most accurate partition values might be obtained on bilayer disks.</p><p>Drug partition data obtained on immobilized model membranes include both hydrophobic and electrostatic interactions. Such partition data should preferably be used when deriving algorithms or computer programs for prediction of drug absorption.</p> Biochemistry Bilayer disk Cholesterol Drug partitioning Drugs Electrostatic effects Immobilized liposome chromatography Liposome Membrane protein Model membrane Oligonucleotide-liposome complex Phospholipid Phospholipid bilayer Proteoliposome Surfactant Biokemi Biochemistry Biokemi
417	Méthode de Perturbation pour la Modélisation par Éléments Finis des Systèmes Électrostatiques en Mouvement - Application aux MEMS Électrostatiques Boutaayamou, Mohamed 05 March 2009 (has links) La modélisation par éléments finis des conducteurs en mouvement nécessite généralement des calculs successifs et le remalliage de certaines régions. Une modélisation 3D de géométries complexes par les techniques classiques nécessite dès lors de gros efforts en terme de temps de calcul. Dans cette thèse, une méthode originale basée sur une approche par sous-problèmes, appelée méthode de perturbation, a été développée. Utilisant la méthode des éléments finis, cette technique consiste à subdiviser un problème entier en sous-problèmes. La complexité du problème initial est par conséquent diminuée en ne se concentrant que sur les zones les plus pertinentes. Appliquée aux systèmes en mouvement, la méthode de perturbation permet d'exploiter les résolutions antérieures au lieu d'effectuer un nouveau calcul pour chaque position. L'analyse par la méthode de perturbation des microsystèmes électromécaniques (MEMS) électrostatiques comprenant des parties en déplacement ou en déformation est en outre considérée dans ce travail. Il est notamment question de démontrer l'implication naturelle de cette approche pour des simulations plus efficaces et plus précises des MEMS électrostatiques. MEMS field distortions / distorsions du champ
418	Development of amperometric biosensor with cyclopentadienylruthenium (II) thiolato schiff base self-assembled monolayer (SAM) on gold Ticha, Lawrence Awa January 2007 (has links) A novel cyclopentadienylruthenium(II) thiolato Schiff base, [Ru(SC6H4NC(H)C6H4OCH2CH2SMe)(&eta / 5-C2H5]2 was synthesized and deposited as a selfassembled monolayer (SAM) on a gold electrode. Effective electronic communication between the Ru(II) centers and the gold electrode was established by electrostatically cycling the Shiff base-doped gold electrode in 0.1 M NaOH from -200 mV to +600 mV. The SAMmodified gold electrode (Au/SAM) exhibited quasi-reversible electrochemistry. The integrity of this electro-catalytic SAM, with respect to its ability to block and electro-catalyze certain Faradaic processes, was interrogated using Cyclic and Osteryoung Square Wave voltammetric experiments. The formal potential, E0', varied with pH to give a slope of about - 34 mV pH-1. The surface concentration, &Gamma / , of the ruthenium redox centers was found to be 1.591 x 10-11 mol cm-2. By electrostatically doping the Au/SAM/Horseradish peroxidase at an applied potential of +700 mV vs Ag/AgCl, a biosensor was produced for the amperometric analysis of hydrogen peroxide, cumene hydroperoxide and tert-butylhydroperoxide. The electrocatalytic-type biosensors displayed typical Michaelis-Menten kinetics with their limits of detection of 6.45 &mu / M, 6.92 &mu / M and 7.01 &mu / M for hydrogen peroxide, cumene hydroperoxide and tert-butylhydroperoxide respectively.
419	Experimental Investigations of Wave Motion and Electric Resistance in Collisionfree Plasmas Wendt, Martin January 2001 (has links) No description available. Beam-plasma Buneman Instability Density gradient Double layer Electric field measurement Electron beam Electrostatic eigenmode Finite element HF probe PIC simulation van der Pol oscillator
420	The birth and growth of the protein folding nucleus : Studies of protein folding focused on critical contacts, topology and ionic interactions Hedberg, Linda January 2008 (has links) Proteins are among the most complex molecules in the cell and they play a major role in life itself. The complexity is not restricted to just structure and function, but also embraces the protein folding reaction. Within the field of protein folding, the focus of this thesis is on the features of the folding transition state in terms of growing contacts, common nucleation motifs and the contribution of charged residues to stability and folding kinetics. During the resent decade, the importance of a certain residue in structure formation has been deduced from Φ-value analysis. As a complement to Φ-value analysis, I present how scatter in a Hammond plot is related to site-specific information of contact formation, Φ´(βTS), and this new formalism was experimentally tested on the protein L23. The results show that the contacts with highest Φ growth at the barrier top were distributed like a second layer outside the folding nucleus. This contact layer is the critical interactions needed to be formed to overcome the entropic barrier. Furthermore, the nature of the folding nucleus has been shown to be very similar among proteins with homologous structures and, in the split β-α-β family the proteins favour a two-strand-helix motif. Here I show that the two-strand-helix motif is also present in the ribosomal protein S6 from A. aeolicus even though the nucleation and core composition of this protein differ from other related structure-homologues. In contrast to nucleation and contact growth, which are events driven by the hydrophobic effect, my most recent work is focused on electrostatic effects. By pH titration and protein engineering the charge content of S6 from T. thermophilus was altered and the results show that the charged groups at the protein surface might not be crucial for protein stability but, indeed, have impact on folding kinetics. Furthermore, by site-specific removal of all acidic groups the entire pH dependence of protein stability was depleted. protein folding protein stability two-state folding chevron plot transition-state movements Hammond behaviour topology electrostatic interactions pH dependence mass-action protein engineering pKa Biochemistry Biokemi

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