Optical characterization of potential drugs and drug delivery systems

Rosenbaum, Erik

January 2011

This Thesis is a characterization study on substances having potency as drugs as well as on a lipid based drug-delivery matrix. The optical properties of newly synthesized molecules with proven pilicide properties have been characterized with several spectroscopic methods. These methods include optical absorption and fluorescence as well as time-resolved fluorescence. Upon covalently linking compounds with high quantum yields of fluorescence to specific parts of the pilicide, the biological impact was found to increase for some of the derivatives. Furthermore, by expanding the aromatic part of the pilicide molecule, a significant increase in the inherent fluorescence was obtained. The S0-S1 absorption band for these molecules was found to originate from an impure electronic transition, vibronically promoted by intensity borrowing from higher electronic states. Included in this Thesis is the measurement of how deeply some in this class of newly synthesized molecules become situated when placed inside ganglioside GM1 micelles, and how the molecules’ reorientation is affected. By means of radiation-less energy transfer, it was shown that the molecules place themselves close to the hydrophobic-hydrophilic interface inside the GM1 micelles. As a consequence they are exposed to a densely packed environment, which inhibits the free tumbling of the molecule. This restricted tumbling could be measured by means of time-resolved depolarization experiments. The release of drug-like fluorescent molecules is investigated from a lipid mixture, which upon equilibrium with water forms a mixture of inverted hexagonal and cubic phases. The lipid matrix displayed an extended release over the course of weeks, in vitro, for molecules having a large variation in hydrophobicity.

Pilicide

Ganglioside GM1 micelles

Drug Delivery

Elecronic Energy Transfer

UV-Vis Absorption

Fluorescence Spectroscopy

Biophysical chemistry

Biofysikalisk kemi

Film Formation of Water-borne Polymer Dispersion: Designed Polymer Diffusion for High Performance Low VOC Emission Coatings

Soleimani Kheibari, Mohsen

31 August 2012

In this thesis, I describe experiments that were designed to provide a better understanding of polymer diffusion during latex film formation. This step leads to the improvement of film mechanical properties. Polymer diffusion in these films was monitored by fluorescence resonance energy transfer. Current paint formulations contain Volatile Organic Compounds (VOCs) as plasticizers to facilitate polymer diffusion. The drawback of this technology is the release of VOCs to the atmosphere. VOCs are deleterious to the environment and contribute to smog and ground level ozone formation. The propensity of water, an indispensible part of any latex dispersion, to promote polymer diffusion was studied. Copolymers of poly (butyl acrylate-co-methyl methacrylate) and poly(ethylhexyl acrylate-co-tertiary butyl methacrylate) with similar glass transition temperatures but different hydrophobicity were compared. Polymer diffusion was monitored for films aged at different relative humidities. Water absorbed by the hydrophobic copolymer film was less efficient in promoting polymer diffusion than in the hydrophilic polymer. Only the fraction of water which is molecularly dissolved in the film participate actively in plasticization. Although water has low solubility in most latex polymers, molecularly dissolved water is more efficient than many traditional plasticizers. The possibility of modifying film formation behavior of acrylic dispersions with oligomers was studied by synthesizing hybrid polymer particles consisting of a high molecular weigh (high-M) polymer and an oligomer with the same composition. Oligomers with lower molecular weight are more efficient as diffusion promoters and have less deleterious effect on high-M polymer viscosity. A different set of hybrid particles were prepared in which the oligomer contained methacrylic acid units. The composition of the oligomer was tuned to be miscible with the high-M polymer when the acid groups were protonated but to phase separate when the acid groups were deprotonated. At basic pH, these particles adopt a core-shell morphology, with a shell rich in neutralized oligomers. After film formation, the oligomer shell retarded polymer diffusion. This retardation is expected to expand the time window during which the paint surface can be altered without leaving brush marks (open time). Short open time is a pressing problem in current technology.

Polymer Diffusion

Latex Dispersions

Film Formation

Volatile Organic Compounds (VOC)

Fluorescence Resonance Energy Transfer

0495

0542

0795

Film Formation of Water-borne Polymer Dispersion: Designed Polymer Diffusion for High Performance Low VOC Emission Coatings

Soleimani Kheibari, Mohsen

31 August 2012

In this thesis, I describe experiments that were designed to provide a better understanding of polymer diffusion during latex film formation. This step leads to the improvement of film mechanical properties. Polymer diffusion in these films was monitored by fluorescence resonance energy transfer. Current paint formulations contain Volatile Organic Compounds (VOCs) as plasticizers to facilitate polymer diffusion. The drawback of this technology is the release of VOCs to the atmosphere. VOCs are deleterious to the environment and contribute to smog and ground level ozone formation. The propensity of water, an indispensible part of any latex dispersion, to promote polymer diffusion was studied. Copolymers of poly (butyl acrylate-co-methyl methacrylate) and poly(ethylhexyl acrylate-co-tertiary butyl methacrylate) with similar glass transition temperatures but different hydrophobicity were compared. Polymer diffusion was monitored for films aged at different relative humidities. Water absorbed by the hydrophobic copolymer film was less efficient in promoting polymer diffusion than in the hydrophilic polymer. Only the fraction of water which is molecularly dissolved in the film participate actively in plasticization. Although water has low solubility in most latex polymers, molecularly dissolved water is more efficient than many traditional plasticizers. The possibility of modifying film formation behavior of acrylic dispersions with oligomers was studied by synthesizing hybrid polymer particles consisting of a high molecular weigh (high-M) polymer and an oligomer with the same composition. Oligomers with lower molecular weight are more efficient as diffusion promoters and have less deleterious effect on high-M polymer viscosity. A different set of hybrid particles were prepared in which the oligomer contained methacrylic acid units. The composition of the oligomer was tuned to be miscible with the high-M polymer when the acid groups were protonated but to phase separate when the acid groups were deprotonated. At basic pH, these particles adopt a core-shell morphology, with a shell rich in neutralized oligomers. After film formation, the oligomer shell retarded polymer diffusion. This retardation is expected to expand the time window during which the paint surface can be altered without leaving brush marks (open time). Short open time is a pressing problem in current technology.

Polymer Diffusion

Latex Dispersions

Film Formation

Volatile Organic Compounds (VOC)

Fluorescence Resonance Energy Transfer

0495

0542

0795

Objective Approaches to Single-Molecule Time Series Analysis

Taylor, James

24 July 2013

Single-molecule spectroscopy has provided a means to uncover pathways and heterogeneities that were previously hidden beneath the ensemble average. Such heterogeneity, however, is often obscured by the artifacts of experimental noise and the occurrence of undesired processes within the experimental medium. This has subsequently caused in the need for new analytical methodologies. It is particularly important that objectivity be maintained in the development of new analytical methodology so that bias is not introduced and the results improperly characterized. The research presented herein identifies two such sources of experimental uncertainty, and constructs objective approaches to reduce their effects in the experimental results. The first, photoblinking, arises from the occupation of dark electronic states within the probe molecule, resulting in experimental data that is distorted by its contribution. A method based in Bayesian inference is developed, and is found to nearly eliminate photoblinks from the experimental data while minimally affecting the remaining data and maintaining objectivity. The second source of uncertainty is electronic shot-noise, which arises as a result of Poissonian photon collection. A method based in wavelet decomposition is constructed and applied to simulated and experimental data. It is iii found that, while making only one assumption, that photon collection is indeed a Poisson process, up to 75% of the shot-noise contribution may be removed from the experimental signal by the wavelet-based procedure. Lastly, in an effort to connect model-based approaches such as molecular dynamics simulation to model-free approaches that rely solely on the experimental data, a coarse-grained molecular model of a molecular ionic fluorophore diffusing within an electrostatically charged polymer brush is constructed and characterized. It is found that, while the characteristics of the coarse-grained simulation compare well with atomistic simulations, the model is lacking in its representation of the electrostatically-driven behavior of the experimental system.

Single-Molecule

Fluorescence Resonance Energy Transfer

Bayesian Inference

Wavelets

Coarse-Grained Molecular Dynamics

Fluorescence Correlation Spectroscopy

Time Series Analysis

Charge-Transfer Associated Photoluminescence Of Rare-Earths Doped Oxide Phosphors

Nag, Abanti

08 1900

Luminescent materials can be found in a broad range of everyday applications. While in the seventies and eighties, the field of luminescent materials seemed to be fairly well covered, research in nineties has been revitalized both in industry and academia. Improvements over the last three decades have led to phosphor materials that operate close to their physical limits. It cannot be expected that properties such as quantum yield and spectral energy distribution will be significantly improved or that distinctly better materials will be found in the near future. Recently, there is a considerable research activity in the field of luminescent materials for lighting and displays to improve the chemical stability and to adopt the materials to the production technology. Ongoing miniaturization, lifetime improvement and spectral stability of fluorescent lamps on the one hand and brightness and contrast improvement in imaging systems on the other hand demand luminescent materials with very high stability that is invariable to operating conditions. All of the today's efficient lighting sources are based on either direct or indirect light emission from plasma discharges. During the pioneering stage, fluorescent lamp industries predominantly used mixtures of two photo luminescent materials: (Zn,Be)2SiO4.'Mn2+ having two emission maxima at 520 and 600 nm and MgW04 with 480 nm emission. The emission from these two phosphors covers the major portion of the visible spectrum. However, the compound (Zn,Be)2Si04 is hazardous to health because of its beryllium content. In 1942, Jenkins showed that Ca5(PO4)3(F,Cl):Sb,Mn was a very efficient emitter. The halophosphates emit both in the blue (Sb3+) as well as in the orange (Mn2+) spectral region, thus in addition yield white light. By carefully adjusting the ratio of Sb3+ and Mn2+ ion concentrations, a white light emitting phosphor was obtained with color temperatures ranging between 6500 and 2700K. However, the drawback of the halophosphate lamps is that it is impossible to have simultaneously high brightness and high color rendering; if the brightness is high (efficacy -80 lm W"1), the color rendering index (CRI) is of the order of 60, the CRI value can be improved up to 90, but then brightness decreases (-50 lm W"1). In 1974, another important breakthrough came in the form of compact fluorescent lamp, based on the trichromatic phosphor blend which resulted color rending values of 80-85 (color 80 lamps) at high efficiencies of 100 lm W"1. The fluorescent lamps with very high color rendering and efficiency can be obtained if three narrow band emitters with emission maxima at 450, 540 and 610 nm are employed. A typical trichromatic lamp phosphor blend comprises of (i) Sr5(PO4)3Cl:Eu2\ BaMgAl1()O,7:Eu2' as blue component, (ii) Ce0.67Tbo.33MgAl,,0,9, LaPO4,Le3\Tb3+ as green component and (iii)Y2C>3:Eiru as the red component. The color 80 lamps employ line emitters that generated light in discrete wavelength intervals. Colored objects that absorb outside these spectral regions appear with a slightly different body color when illuminated with these lamps rather than with a black body radiator such as the light bulb. For these purposes, color 90 or Deluxe lamps have been developed. The emission maximum of the blue phosphor can be shifted towards longer Wavelength by substituting BaMgAli0Oi7:Eu2+ with Sr4Ali4025:Eu2+. The red and green line emitters can be substituted by broad band emitters covering the whole spectral range. For this concept, (Ce,Gd,Tb)MgB5Oi0:Mn has been developed as a red emitter in which energy transfer from Ce3+ via Gd3+ to Mn2+ gives rise to an additional broad band at 630 nm. On the other hand, (Ba,Sr,Ca)2Si04:Eu has been developed as an alternative green-band emitter in which depending on the exact composition, the phosphor emits between 550 and 580 nm with a high quantum yield. Unfortunately, the host lattice is not stable in water, which prevents its deposition on the lamp bulb from aqueous suspensions and for environmental reasons more and more lamps producers use water as the suspending solvent in production instead of butyl acetate. Therefore, it is necessary to develop a new full color emitting phosphors, which has both thermal and chemical stability for application in luminescent lighting. The classical cathode ray tube (CRT) invented as the brown tube more than 100 years ago has developed into a remarkably mature product considering the complexity of its manufacturing process. Cathode rays are a beam of fast electrons, the accelerating voltage in a television picture tube is high (>10 kV). Basic requirements of display phosphors are stability (2000 hr operation) and emission color purity according to the standards set by the European Broadcasting Union (EBU). The blue and green phosphors are still the very cheep ZnS based materials, essentially the same ever since color-TV was introduced in fifties. On the other hand, (Zn,Cd)S, Ag+,C1" was originally used as the red phosphor however, the broad emission centered at 650 nm due to intrinsic donor-acceptor transition leads to rather low lumen equivalent as large fraction of the emission integral lies outside the eye sensitivity curve. For this and the environmental reasons, it has been replaced by the much more expensive Y2O2S:Eu with main emission lines at 612 and 628 nm. Recently, the big electronic companies are trying to enforce flat panel displays e.g. PDPs (plasma display panels) and FEDs (field emission displays). This is because of the fact that when compared to the CRT screen pigments, FED phosphors are required to operate at lower voltages and higher current densities. Although the voltages used in FEDs are only 0.1 to < 2 kV, the high-energy surface excitation on the phosphor particles causes degradation of sulfides, leaving the oxide hosts as the only favorable choice. The phosphor blends used are mixtures of SrTiO3:Pr3+ (red), Y2Si05:Tb (green) and Y2Si05:Ce (blue). However, the white light generation efficiency is very low (-5 lm W"1) and required improvement of phosphor efficacy because of its distinct advantages such as a very wide range of operational temperatures, stability under rugged conditions and wide viewing angle of emission. Similarly, in PDPs blue emitting BaMgAlioOniEu, green emitting Z^SiO^Mn and red emitting (Y,Gd)BO3:Eu are mostly used which shows a screen efficiency of about 1.5 lm W"1, just only half that of a CRT used in today's TV sets. However, the advantages of PDPs over CRTs are that it is not sensitive towards the display manufacturing process, which includes high temperature annealing up to about 600°C and it is stable under the harsh conditions of a Ne/Xe plasma used in PDPs (ion bombardment, VUV radiation). This puts pressure on the development of phosphor for maximum brightness and high stability to replace completely the classical CRTs. On the other hand, the invention of the blue-light emitting diode (LED) based on GaN can be regarded as a triumph of materials chemistry. In principle, it is possible to vary the emission wavelength of blue GaN-based LEDs between 370 nm (band-gap of pure GaN) and 470 nm by increasing the indium (In) content in InGaN devices. Assuming a conversion from the incident light by a phosphor material emitting at 555 nm, InGaN is coated with (Yi.xGdx)3(Ali-yGay)5Oi2:Ce (YAG:Ce) which has broad yellow band varying between 510 and 580 nm. This allows the adjustment of white color temperature from 8000 down to 3000 K. Recently, S^SiCU and S^SiOs have attracted current interest due to their potential applications in developing white light-emitting-diodes (LEDs) because GaN (400 nm chip)-coated with Sr2Si04:Eu2+ or Sr3SiC>5;Eu2+ exhibits better luminous efficiency than that of the industrially available product such as InGaN (460 nm chip)-coated with YAG:Ce. However, the major drawback of this combination is the strongly decreasing overall efficiency upon lowering the color temperature. This can be solved by using a phosphor material that has sufficient absorption at the emission wavelength of the blue diode, the quantum yield should be high under UV/Vis excitation and the FWHM of the emission band should be as small as possible in order to achieve high luminous output. The search for stable inorganic rare-earths phosphors with high absoiption in the near UV/blue spectral region is therefore an attractive research work. Since luminescence materials are a key component for lighting and display concept, research in the field of rare-earths doped oxide phosphors is carried out. Although state-of-the-art materials fulfill most requirements, improvements are still necessary to further boost the efficiency of the phosphor materials. Since it is not expected that materials will be found that perform better than the already established phosphor, the present work concentrates on the improvements of the phosphor by modifying the chemical and niicrostructurai features as well as the crystal structure. Chapter I gives a brief introduction to luminescence in solids, physical aspects and applications. Chapter II describes the synthesis and various experimental techniques employed in the investigation. Chapter III deals with photoluminescence and energy transfer involving charge transfer states in Sr2-xLnxCe04+x/2 (Ln = Eu and Sm) leading to an efficient full color emitting phosphor for luminescent lighting. Chapter IV and V describe charge transfer transition involving interface states associated with transitional nanophaseprecipitates leading to photoluminescence enhancement of SrTiO3:Pr3+,Al3+ and SrAli2Oi9:Pr3+,Ti4\ The light induced charge transfer leading to changing oxidation state of Eu in Sr2Si04 involving transient crystal structure results an efficient material for optical storage is presented in Chapter VI.Photoluminescence due to efficient energy transfer from Ce3+ to Tb3+ and Mn2t in SnAlioSi02o leading to an efficient phosphor for FEDs is presented in Chapter VII. Chapter VIII describes charge transfer transition involving trap states leading to long phosphorescence in SrAl2-xBxO4 (0<x<0.2) and Sr4Al14.xBxO25 (0.1<x<0.4) co-doped with Eu2+ and Dy3+. Chapter IX presents the role of particle size on the charge transfer associated luminescence of GdVO4:Ln3+ (Ln = Eu and Sm). A summary of the important findings and the conclusions arrived on the basis of results from these investigations are presented at the end of the thesis.

Photoluminescence

Phosphorescence

Oxide Phosphors - Doping

Luminescence

Luminescent Materials

Phosphorescent Materials

Luminescent Center

Phosphor Materials

Energy Transfer

Transitional Nanophase Precipitates

Optics

The Mechanism and Regulation of Chromatin Remodeling by ISWI Family Enzymes

Hwang, William Liang

January 2013

Eukaryotic genomes are packaged as chromatin, which restricts access to the DNA by critical processes such as DNA replication, repair, and transcription. As a result, eukaryotic cells rely on ATP-dependent chromatin remodeling enzymes (remodelers) to alter the position, structure, and composition of nucleosomes. Understanding the mechanism and regulation of remodeling requires detailed information about transient intermediates of the remodeling process--a challenge ideally suited for single-molecule approaches. In particular, we use single-molecule fluorescence resonance energy transfer (smFRET) to measure nanometer-scale distance changes between strategically placed donor and acceptor dyes to monitor nucleosome translocation in real-time. The mechanism(s) by which remodelers use the free energy of ATP hydrolysis to disrupt histone-DNA contacts and reposition nucleosomes are not well understood. Using smFRET, we show that remodeling by ISWI enzymes begins with a 7 base-pair (bp) step followed by subsequent 3 bp steps toward the exit-side of the nucleosome. These multi-bp steps are actually compound steps composed of 1 bp elementary steps. We discover that DNA movement on the entry side lags behind exit side translocation, which is contrary to previously proposed models. Based on our results, we propose a new integrated mechanism for nucleosome translocation by ISWI enzymes. In the physiological context, remodelers are highly regulated. We study the regulation of human ACF, a prototypical ISWI complex, by critical features of the nucleosomal substrate. First, we dissect how the nucleosome translocation cycle is affected by the linker DNA length and histone H4 tail. Next, we introduce mutations/deletions into conserved enzyme domains to determine the mechanism by which linker length information sensed by the Acfl accessory subunit is allosterically transmitted to the Snf2h catalytic subunit. Interestingly, we find that Acfl modulates the activity of Snf2h indirectly by interacting with the H4 tail in a linker-length dependent fashion. While the majority of our experiments focus on observing changes in nucleosome position, we also develop strategies for site-specific labeling of ISWI enzymes and demonstrate their use in the study of dynamic enzyme-substrate interactions and enzyme conformational changes.

Biophysics

Molecular biology

Biochemistry

Chromatin Remodeling Enzymes

Fluorescence Resonance Energy Transfer

ISWI

Mechanism

Nucleosome Translocation and Spacing

Single-Molecule

Molecular Beam Studies of Energy Transfer in Molecule Surface Interactions / Untersuchung des Energietransfers in Molekuel Oberflaechen Wechselwirkungen mit Hilfe von Molekularstrahlexperimenten

Russell, James Cooper

29 November 2011

No description available.

540 Chemie

Chemistry

Energietransfer

Molekularstrahl

Oberflaechen

Schwingungs

laserspektroskopischen

Energy transfer

Molecular beams

surfaces

molecular vibration

laser spectroscopy

35

S

Primary Effects of X-ray and Photo-Absorption Induced Excitations in Biomolecules

Burmeister, Carl Friedrich

11 April 2013

No description available.

530

Physik (PPN621336750)

electron dynamics

time-dependent hartree-fock

molecular dynamics

surface hopping

photo-active yellow protein

excitation energy transfer

Structural vibration damping with synchronized energy transfer between piezoelectric patches

Li, Kaixiang

22 September 2011

Advanced materials such as carbon fiber, composite materials et al. are more and more used in modern industry. They make the structures lighter and stiffer. However, they bring vibration problems. Researchers studied numerous methods to eliminate the undesirable vibrations. These treatments are expected to be a compact, light, intellectual and modular system. Recently, a nonlinear technique which is known as Synchronized Switch Damping (SSD) technique was proposed. These techniques synchronously switched when structure got to its displacement extremes that leading to a nonlinear voltage on the piezoelectric elements. This resulting voltage showed a time lag with the piezoelectric strain thus causing energy dissipation. Based on the developed SSD techniques, a new synchronized switch damping e.g. Synchronized Switch Damping with Energy Transfer (SSDET) was proposed in this document. This method damped the vibration by using the energy from other vibrating form. The objectives of the work reported in this document were threefold. The first one consisted of introduction of SSDET principle and developing its control law. This part aimed at establishing the mathematical model and verifying the proposed method by mathematical tools. Then, the experimental validations were carried out. Three experiments with different configurations demonstrated that SSDET can be implemented not only between structures but also vibrating modes in one structure. A SSDET scheme with multi-patches was also investigated for improving the damping. Finally, a bidirectional SSDET concept was introduced based on the original SSDET technique. This technique be regarded as a multimode control SSDET. Since it privileged the target vibration while keeps a decent control effect on the source vibration.

[SPI:OTHER] Engineering Sciences/Other

Electrotechnics

Piezoelectric Component

Vibration Damping

Non linear vibration control

Semi passive effect

Semi active effect

Energy transfer

Bevielio energijos perdavimo tyrimas / Investigation of the wireless energy transfer

Ermanas, Žilvinas

18 June 2013

Šiandien neįsivaizduojame savo gyvenimo be daugybės elektrą naudojančių prietaisų, kurie su elektros šaltiniu sujungti elektros laidais. Daugybė besipainiojančių laidų tikrai nepadaro mūsų gyvenimo lengvesnio ir patogesnio. Dar labiau komplikuoja situacijas, kai neįmanoma panaudoti laidų ir prisijungti prie energijos šaltinio. Visi šie nepatogumai skatina ieškoti išeities, kuri galėtų būti energijos perdavimas be laidų. Bevielės elektros idėja buvo iškelta jau prieš daugiau kaip šimtą metų, tai buvo išradėjo Nikola Tesla mintis. Darbui nagrinėti pagamintas bevielės energijos perdavimo demonstracinis modelis. Modelyje nagrinėjama bevielės energijos perdavimo sistema, veikimo principas, siunčiamos energijos nuotolis, perduodamos energijos efektyvumas bei gaunami nuostoliai. / Today can not imagine our life without many electricity using devices are connected to a source of electrical power lines. Numerous trailing wires really does not make our lives easier and more comfortable. Even more complicated situations when there are no opportunities to use wire and to connect to a power source. All these inconveniences are promoting to search the solution wich could be the transfer of energy without wires. Wireless energy idea has been raised for more than a hundred years ago. The thought was inventor inventored by Nikola Tesla. Analyzing this work there was made a demonstration model of wireless power transmission. In this model there is analyzing such things as wireless transmission system, working principal, transmitted energy distance and obtained losses.

Electronics and Electrical Engineering

Bevielis energijos perdavimas

Abipusis induktyvumas

Aukštas dažnis

Wireless energy transfer

Mutual inductance

High frequency