Global ETD Search

151	Design and Simulation of Nano-plasmonic Filter based on Nonlinear Nanocavity Mollaei, Yaghoub, Shahmohammadi, Kaveh January 2019 (has links) No description available. Surface Plasmon Polaritons Nonlinear Optics Filter Nanocavity Elektroteknik och elektronik
152	The extraordinary infrared transmission of metal microarrays for enhanced absorption spectroscopy of monolayers, nanocoatings, and catalytic surface reactions Rodriguez, Kenneth Ralph, January 2007 (has links) Thesis (Ph. D.)--Ohio State University, 2007. / Title from first page of PDF file. Includes bibliographical references (p. 361-380).
153	Synthesis of azide- and alkyne-terminated alkane thiols and evaluation of their application in Huisgen 1,3-dipolar cycloaddition ("click") reactions on gold surfaces Okabayashi, Yohei January 2009 (has links) <p>Immobilization of different bio- and organic molecules on solid supports is fundamental within many areas of science. Sometimes, it is desirable to obtain a directed orientation of the molecule in the immobilized state. In this thesis, the copper (I) catalyzed Huisgen 1,3-dipolar cycloaddition, referred to as a “click chemistry” reaction, was explored as a means to perform directed immobilization of small molecule ligands on gold surfaces. The aim was to synthesize alkyne- and azide-terminated alkanethiols that would form well-organized self assembled monolayers (SAMs) on gold from the commercially available substances orthoethylene glycol and bromo alkanoic acid. N-(23-azido-3,6,9,12,15,18,21-heptaoxatricosyl)-n-mercaptododekanamide/hexadecaneamide (n = 12, 16) were successfully synthesized and allowed to form SAMs of different compositions to study how the differences in density of the functional groups on the surface would influence the structure of the monolayer and the click chemistry reaction. The surfaces were characterized by different optical methods: ellipsometry, contact angle goniometry and infrared reflection-absorption spectroscopy (IRAS). The click reaction was found to proceed at very high yields on all investigated surfaces. Finally, the biomolecular interaction between a ligand immobilized by click chemistry on the gold surfaces and a model protein (bovine carbonic anhydrase) was demonstrated by surface plasmon resonance using a Biacore system.</p> Self-Assembled monolayers Click Chemistry Surface Plasmon Resonance Organic chemistry Organisk kemi
154	Protein Microarray Chips Klenkar, Goran January 2007 (has links) Livet tas för givet av de flesta. Det finns däremot många som ägnar stora delar av sitt liv för att försöka lösa dess mysterier. En del av lösningen ligger i att förstå hur alla molekyler är sammanlänkade i det gigantiska nätverk som definierar den levande organismen. Under det senaste seklet har en hel del forskning utförts för att kartlägga dessa nätverk. Resultatet av dessa mödor kan vi se i de läkemedel som vi har idag och som har utvecklats för att bota eller åtminstone lindra olika sjukdomar och tillstånd. Dessvärre finns det fortfarande många sjukdomar som är obotliga (t.ex. cancer) och mycket arbete krävs för att förstå dem till fullo och kunna designa framgångsrika behandlingar. Arbetet i denna avhandling beskriver en analytisk plattform som kan användas för att effektivisera kartläggningsprocessen; protein-mikroarrayer. Mikroarrayer är ytor som har mikrometerstora (tusendels millimeter) strukturer i ett regelbundet mönster med möjligheten att studera många interaktioner mellan biologiska molekyler samtidigt. Detta medför snabbare och fler analyser - till en lägre kostnad. Protein-mikroarrayer har funnits i ungefär ett decennium och har följt i fotspåren av de framgångsrika DNA-mikroarrayerna. Man bedömer att protein-mikroarrayerna har en minst lika stor potential som DNA mikroarrayerna då det egentligen är mer relevant att studera proteiner, som är de funktionsreglerande molekylerna i en organism. Vi har i detta arbete tillverkat modellytor för stabil inbindning av proteiner, som lämnar dem intakta, funktionella och korrekt orienterade i ett mikroarray format. Därmed har vi adresserat ett stort problem med protein mikroarrays, nämligen att proteiner är känsliga molekyler och har i många fall svårt att överleva tillverkningsprocessen av mikroarrayerna. Vi har även studerat en metod att tillverka mikroarrayer av proteiner bundna till strukturer, som modellerats att efterlikna cellytor. Detta är särkilt viktigt eftersom många (hälften) av dagens (och säkerligen framtidens) läkemedel är riktade mot att påverka denna typ av proteiner och att studera dessa i sin naturliga miljö är därför väldigt relevant. I ett annat projekt har vi använt protein mikroarrayer för att detektera fyra vanliga droger (heroin, amfetamin, ecstasy och kokain). Detektionen baseras på användandet av antikroppar som lossnar från platser på ytan när de kommer i kontakt med ett narkotikum. Detta koncept kan enkelt utvecklas till att detektera mer än bara fyra droger. Vi har även lyckats att parallellt mäta förekomsten av en annan typ av förening på mikroarray ytan, nämligen det explosiva ämnet trinitrotoluen (TNT). Detta visar på en mångsidig plattform för detektionen av i princip vilken typ av farlig eller olaglig substans som helst - och på en yta! Vi föreställer oss därför att möjliga tillämpningsområden finns inom brottsbekämpning, i kampen mot terrorism och mot narkotikamissbruk etc. Mikroarrayerna har i denna avhandling utforskats med optiska metoder som tillåter studie av omärkta proteiner, vilket resulterar i så naturliga molekyler som möjligt. / Life is a thing taken for granted by most. However, it is the life-long quest of many to unravel the mysteries of it. Understanding and characterizing the incomprehensively complex molecular interaction networks within a biological organism, which defines that organism, is a vital prerequisite to understand life itself. Already, there has been a lot of research conducted and a large knowledge has been obtained about these pathways over, especially, the last century. We have seen the fruits of these labors in e.g. the development of medicines which have been able to cure or at least arrest many diseases and conditions. However, many diseases are still incurable (e.g. cancer) and a lot more work is still needed for understanding them fully and designing successful treatments. This work describes a generic analytical tool platform for aiding in more efficient (bio)molecular interaction mapping analyses; protein microarray chips. Microarray chips are surfaces with micrometer sized features with the possibility of studying the interactions of many (thousands to tens of thousands) (bio)molecules in parallel. This allows for a higher throughput of analyses to be performed at a reduced time and cost. Protein microarrays have been around for approximately a decade, following in the footsteps of the, so far, more successfully used DNA microarrays (developed in the 1990s). Microarrays of proteins are more difficult to produce because of the more complex nature of proteins as compared to DNA. In our work we have constructed model surfaces which allow for the stable, highly oriented, and functional immobilization of proteins in an array format. Our capture molecules are based on multivalent units of the chelator nitrilotriacetic acid (NTA), which is able to bind histidine-tagged proteins. Furthermore, we have explored an approach for studying lipid membrane bound systems, e.g. receptor-ligand interactions, in a parallelized, microarray format. The approach relies on the addressable, DNA-mediated adsorption of tagged lipid vesicles. In an analogous work we have used the protein microarray concept for the detection of four common narcotics (heroin, amphetamine, ecstasy, and cocaine). The detection is based on the displacement of loosely bound antibodies from surface array positions upon injection of a specific target analyte, i.e. a narcotic substance. The proof-of-concept chip can easily be expanded to monitor many more narcotic substances. In addition, we have also been able to simultaneously detect the explosive trinitrotoluene (TNT) along with the narcotics, showing that the chip is a versatile platform for the detection of virtually any type of harmful or illegal compound. This type of biosensor system is potentially envisaged to be used in the fight against crime, terrorism, drug abuse etc. Infrared reflection absorption spectroscopy together with ellipsometry has been used to characterize molecular layers used in the fabrication processes of the microarray features. Imaging surface plasmon resonance operating in the ellipsometric mode is subsequently used for functional evaluation of the microarrays using a well-defined receptor-ligand model system. This approach allows simultaneous and continuous monitoring of binding events taking place in multiple regions of interest on the microarray chip. A common characteristic of all the instrumentation used is that there is no requirement for labeling of the biomolecules to be detected, e.g. with fluorescent or radioactive probes. This feature allows for a flexible assay design and the use of more native proteins, without any time-consuming pretreatments. Microarray biosensor biomolecular interaction narcotics detection Molecular biophysics Molekylär biofysik
155	Biosensor technology applied to hybridization analysis and mutation detection Nilsson, Peter January 1998 (has links) This thesis demonstrates the application of biosensor technology for molecular biology investigations, utilizing a surface plasmon resonance based optical device for mass sensitive detection of biomolecular interactions at a chipsurface. Oligonucleotide model systems were designed for analysis of the action of DNA manipulating enzymes. DNA ligation, DNA cleavage and DNA synthesis could be quantitatively monitored in real-time. A protocol for DNA minisequencing was also established based on prevention of chain elongation by incorporation of chain-terminators. Determinations of affinities for short oligonucleotides hybridizing to an immobilized target were performed with various sequence content, length, temperature and degree of complementarity. The decrease in affinity for hybridizations involving mismatch situations was found to be strongly dependent on the relative position of the mismatch. Interestingly, also end-mismatches were clearly detectable. The stabilization effect achieved upon co-hybridization of two adjacently annealing short oligonucleotide modules (modular primer effect) was also investigated for different module combinations and hybridization situations. The modular concept of hybridizations was subsequently demonstrated to result in enhanced Capture of single stranded PCR products. The sequence based DNA analysis, first introduced with oligonucleotide modelsystems, was extended to the scanning and screening formutations in PCR amplified DNA from clinically relevant samples. Several different formats were investigated, eitherwith the PCR products immobilized on the chip and oligonucleotides injected or vice versa. Again, mismatch discrimination could be observed for wild type and mutant specific oligonucleotides hybridizing to the targets. The experimental set-up for mutation detection was further developed by the introduction of a subtractive mismatch sensitive hybridization outside the instrument and a subsequent determination of the relative amounts of remain ingoligonucleotides with analytical biosensor monitoring of hybridizations between fully complementary oligonucleotides. In conclusion, the applied technology was found to be a suitable tool for a wide range of molecular biology applications, with emphasis on hybridization analysis and mutation detection. / QC 20100611 biosensor genosensor surface plasmon resonance hybridization nucleic acids oligonucleotide mutation detection mismatch discrimination modular Bioengineering Bioteknik
156	Synthesis of azide- and alkyne-terminated alkane thiols and evaluation of their application in Huisgen 1,3-dipolar cycloaddition ("click") reactions on gold surfaces Okabayashi, Yohei January 2009 (has links) Immobilization of different bio- and organic molecules on solid supports is fundamental within many areas of science. Sometimes, it is desirable to obtain a directed orientation of the molecule in the immobilized state. In this thesis, the copper (I) catalyzed Huisgen 1,3-dipolar cycloaddition, referred to as a “click chemistry” reaction, was explored as a means to perform directed immobilization of small molecule ligands on gold surfaces. The aim was to synthesize alkyne- and azide-terminated alkanethiols that would form well-organized self assembled monolayers (SAMs) on gold from the commercially available substances orthoethylene glycol and bromo alkanoic acid. N-(23-azido-3,6,9,12,15,18,21-heptaoxatricosyl)-n-mercaptododekanamide/hexadecaneamide (n = 12, 16) were successfully synthesized and allowed to form SAMs of different compositions to study how the differences in density of the functional groups on the surface would influence the structure of the monolayer and the click chemistry reaction. The surfaces were characterized by different optical methods: ellipsometry, contact angle goniometry and infrared reflection-absorption spectroscopy (IRAS). The click reaction was found to proceed at very high yields on all investigated surfaces. Finally, the biomolecular interaction between a ligand immobilized by click chemistry on the gold surfaces and a model protein (bovine carbonic anhydrase) was demonstrated by surface plasmon resonance using a Biacore system. Self-Assembled monolayers Click Chemistry Surface Plasmon Resonance Organic chemistry Organisk kemi
157	Investigation of hPin1 mediated phosphorylation dependency in degradation control of c-Myc oncoprotein Johansson, Malin January 2012 (has links) Cancer is the main cause of death in economically developed countries and the second leading cause of death in developing countries. Along with today’s knowledge that more than two hundred different diseases lie in the category of this prognosis there is an urge for more detailed and case-specific treatments to replace the dramatic actions of available radiation- and chemotherapy, which in many cases do not make a difference between healthy and cancer cells. The transcription factor and onco-protein c-Myc has, after being extensively studied during the past decades, become a prognostic marker for almost all cancer forms known. Still, many questions remain regarding how c-Myc interacts with its many different target proteins involved in cell-cycle regulation, proliferation and apoptosis. Current cell biology states that one of the regulating proteins, hPin1, interacts with c-Myc in a phosphorylation-dependent manner which appears to direct the correct timing of c-Myc activation and degradation through the ubiquitin/proteasome-pathway. The critical phosphorylation sites, T58 and S62, are located in the Myc-Box-I (MBI) region, a highly conserved sequence strongly coupled to aggressive tumourigenesis by hotspot mutations. Interestingly, preliminary results in the Sunnerhagen group suggested that MBI alone did not bind hPin1, suggesting hPin1 targeting a site distal from the residues to be phosphorylated. In this thesis, results from Surface Plasmon Resonance (SPR) and Nuclear Magnetic Resonance (NMR) show that the docking WW-domain of hPin1 binds unphosphorylated c-Myc at a region distal from the phosphorylation site, including residues 13-34. Furthermore, SPR experiments revealed that hPin1 binds unphosphorylated c-Myc with apparently greater affinity and with much slower kinetics than phosphorylated c-Myc. Thus, hPin1 recognition and interaction with c-Myc appears not to be dependent on phosphorylation of c-Myc prior binding. The newly identified binding region of c-Myc, located N-terminal of MBI, may further increase the understanding of protein degradation control and c-Myc function. The studies presented in this thesis provide a brick in the puzzle of c-Myc and hPin1 coupled oncogenesis for further development of new therapeutic strategies. Protein-protein interaction structure biology phosphorylation oncoprotein c-Myc hPin1 Surface Plasmon Resonance Nuclear Magnetic Resonance
158	Amplification of Long-Range Surface Plasmon-Polaritons De Leon Arizpe, Israel 18 February 2011 (has links) Surface plasmon-polaritons are optical surface waves formed through the interaction of photons with free electrons at the surface of metals. They offer interesting applications in a broad range of scientific fields such as physics, chemistry, biology, and material science. However, many of such applications face limitations imposed by the high propagation losses of these waves at visible and near-infrared wavelengths, which result mainly from power dissipation in the metal. In principle, the propagation losses of surface plasmon-polaritons can be compensated through optical amplification. The objective of this thesis is to provide deeper insights on the physics of surface plasmon-polariton amplification and spontaneous emission in surface plasmon-polariton amplifiers through theoretical and experimental vehicles applied (but not necessarily restricted) to a particular plasmonic mode termed long-range surface plasmon-polariton. On the theoretical side, the objective is approached by developing a realistic theoretical model to describe the small-signal amplification of surface plasmon-polaritons in planar structures incorporating dipolar gain media such as organic dye molecules, rare-earth ions, and quantum dots. This model takes into account the inhomogeneous gain distribution formed near the metal surface due to a non-uniform excitation of dipoles and due to a position-dependent excited-state dipole lifetime that results from near-field interactions between the excited dipoles and the metal. Also, a theoretical model to describe the amplified spontaneous emission of surface plasmon-polaritons supported by planar metallic structures is developed. This model takes into account the different energy decay channels into which an exited dipole located in the vicinity of the metal can relax. The validity of this model is confirmed through experimentation. On the experimental side, the objective is approached by providing a direct experimental demonstration of complete loss compensation in a plasmonic waveguide. The experiments are conducted using the long-range surface plasmon-polariton supported by a symmetric thin gold waveguide incorporating optically pumped organic dye molecules in solution as the gain medium. Also, an experimental study of spontaneous emission in a long-range surface plasmon-polariton amplifier is presented. It is shown that this amplifier benefits from a low spontaneous emission into the amplified mode, which leads to an optical amplifier with low noise characteristics. The experimental setup and techniques are explained in detail. Surface plasmon-polaritons Optical amplification Amplified spontaneous emission Stimulated emission Optical waveguides
159	Exciton-plasmon interactions in metal-semiconductor nanostructures Hellström, Staffan January 2012 (has links) Semiconductor quantum dots and metal nanoparticles feature very strong light-matter interactions, which has led to their use in many photonic applications such as photodetectors, biosensors, components for telecommunications etc.Under illumination both structures exhibit collective electron-photon resonances, described in the frameworks of quasiparticles as exciton-polaritons for semiconductors and surface plasmon-polaritons for metals.To date these two approaches to controlling light interactions have usually been treated separately, with just a few simple attempts to consider exciton-plasmon interactions in a system consisting of both semiconductor and metal nanostructures.In this work, the exciton-polaritons and surface \\plasmon-polaritons are first considered separately, and then combined using the Finite Difference Time Domain numerical method coupled with a master equation for the exciton-polariton population dynamics.To better understand the properties of excitons and plasmons, each quasiparticle is used to investigate two open questions - the source of the Stokes shift between the absorption and luminescence peaks in quantum dots, and the source of the photocurrent increase in quantum dot infrared photodetectors coated by a thin metal film with holes. The combined numerical method is then used to study a system consisting of multiple metal nanoparticles close to a quantum dot, a system which has been predicted to exhibit quantum dot-induced transparency, but is demonstrated to just have a weak dip in the absorption. / <p>QC 20120417</p> plasmons excitons quantum dots nanoparticles FDTD surface plasmon polaritons QDIP quantum dot infrared photodetector polaritons
160	Biophysical investigation of M-DNA Wood, David Owen 31 May 2005 M-DNA is a complex formed between normal double-stranded DNA and the transition metal ions Zn2+, Ni2+, and Co2+ that is favoured by an alkaline pH. Previous studies have suggested that M-DNA formation involves replacement of the imino protons of G and T bases by the transition metal ions involved in forming the complex. Owing to the conductive properties of this unique DNA conformation, it has potential applications in nanotechnology and biosensing. This work was aimed at improving existing methods and developing new methods of characterizing M-DNA. The effects of base substitutions, particularly those of G and T, were evaluated in light of the proposed structure. Differences between M-DNA conformations induced by Zn2+ and Ni2+ were also investigated with a variety of techniques and compared to the effects of Cd2+ and Mg2+ on double-stranded DNA. M-DNA formation and stability were studied with an ethidium bromide (EtBr) based assay, M-DNA induced fluorescence quenching of DNA labelled with fluorescein and a compatible quenching molecule, isothermal titration calorimetry (ITC), and surface plasmon resonance (SPR). Production of monoclonal antibodies against the conformation was also attempted but was unsuccessful. The EtBr-based assay showed Ni(II) M-DNA to be much more stable than Zn(II) M-DNA as a function of pH and in the presence of ethylenediaminetetraacetic acid. Sequence-dependency and the effect of base substitutions were measured as a function of pH. With regards to sequence, d(G)nd(C)n tracts were found to form the conformation most easily. Base substitutions with G and T analogues that lowered the pKa of these bases were found to stabilize M-DNA more strongly than other base substitutions. A combination of temperature-dependant EtBr and ITC assays showed M-DNA formation to be endothermic, and therefore entropy driven. The SPR studies demonstrated many qualitative differences between Zn(II) and Ni(II) M-DNA formation, allowed characterization of Zn2+, Ni2+, Cd2+, and Mg2+ complexes with single-stranded DNA, and provided unambiguous evidence that M-DNA formation results in very little denaturation of double-stranded DNA. Specifically, the SPR study showed Ni(II) M-DNA to be more stable than Zn(II) M-DNA in the absence of transition metal ions, but also showed that Ni(II) M-DNA required higher concentrations of Ni2+ than Zn2+ to fully form the respective M-DNA conformations. Finally, quenching studies demonstrated Zn(II) M-DNA formation over a pH range from 6.5 to 8.5 provided that a Zn2+:H+ ratio of roughly 105 was maintained. The Keq for this interaction was 1.3 x 10-8 with 1.4 H+ being liberated per base bair of M-DNA formed. These results support the proposed structural model of M-DNA, as lowering the pKa of the bases having titratable protons over the pH range studied facilitated M-DNA formation. The fact that Zn(II) M-DNA formation was observed by fluorescence quenching at any pH provided that a constant ratio of Zn2+:H+ was maintained was consistent with a simple mass-action interaction for M-DNA formation. The differences between Zn(II) and Ni(II) M-DNA formation show that although it requires a higher pH or transition metal ion concentration, Ni(II) M-DNA is more stable than Zn(II) M-DNA once formed. This difference could play an important role in applications of M-DNA which required modulation in the stability of the M-DNA conformation. Surface Plasmon Resonance Fluorescence DNA-drug interactions DNA-metal ion interactions DNA conformation

Search results