Global ETD Search

11	Electrical characterisation of SIMOX SiOâ†2 for silicon-on-insulator technology Ngwa, Chrisantus Soh January 1996 (has links) No description available. 621.31042 SOI substrates; CMOS Vcircuits
12	Competition-induced selection of ligands for the screening of DNA aptamers for gold substrates Tapp, Maeling Janelle Nicole 27 May 2016 (has links) This dissertation presents the development of an alternative aptamer screening process, Competition-Induced Selection of Ligands (CISL), and its use in screening for ssDNA aptamers for gold substrates. Gold substrates are presented as the nonnucleotide target for implementing CISL as a novel aptamer screening approach. Chapter 1 provides an overview of the in vitro selection of oligonucleotide aptamers, the polymerase chain reaction that is a key step in the aptamer screening process, the synthesis and properties of gold nanoparticles and the biomolecule-mediated formation of inorganic nanoparticles. Chapter 2 presents the goals and objectives of this thesis along with an organizational overview of the dissertation. Chapter 3 describes the experimental techniques and optimizations pertinent to the development of the CISL aptamer screening process. Chapter 4 investigates the effects of various nucleic acid additions during the seed-mediated growth of gold nanoparticles. Chapter 5 discusses the use of CISL in screening for ssDNA aptamer candidates for spherical gold nanoparticles (AuNPs) and the primary and secondary structure analysis of identified sequences. Chapter 6 presents the use of CISL in screening for ssDNA aptamer candidates for planar gold substrates (PlanarAu) and also includes primary and secondary structure analysis of identified sequences accompanied with an incubation study to provide a “frequency” ranking of aptamers as adsorbate species on PlanarAu. Chapter 7 offers concluding remarks and ideas for future expansion and applications of this work. Aptamers Gold nanoparticles Gold substrates SELEX
13	The use of process plasmas for cleaning PCB substrates for fluxless soldering of electronic assemblies Philpott, Justin Dominic January 1999 (has links) No description available. 670
14	Mechanism based inhibitors of tyrosine kinases Page, Timothy C. M. January 1994 (has links) No description available. 572
15	Anisotropic potential HIV-1 protease inhibitors Chong, Sannie Siaw Foong January 1999 (has links) No description available. 615.1
16	Exploring HIV Integrase 3’-processing Using Designed DNA Substrates and Structural Study of HIV DNA Hairpins Li, Qiushi 14 December 2016 (has links) In the HIV viral integration procedure, 3’-processing of the viral DNA by the integrase enzyme is an essential first step which is followed by the integration of viral DNA into the host genome. In 3’-processing, the integrase cleaves the backbone of the DNA substrate on the 3’ end of a conserved CA dinucleotide motif and inserts a helix between the two DNA strands, forcing them apart (Hare, S., 2012). Our study confirms that the presence of a G-amino group is crucial for 3’-processing. Substituting inosine for G in the CA step removes this amino group and results in loss of enzyme activity. Further work showed that the presence of a terminal duplex segment is not required for 3’-processing. Additional substrate modifications are studied in order to evaluate the actual importance of the CA step. HIV Integrase 3’-processing DNA Substrates Inosine
17	Extracellular matrix based substrates for propagation of human pluripotent stem cells Abraham, Sheena 16 February 2010 (has links) In human pluripotent stem cell (hPSC) research and applications, the need for a culture system devoid of non-human components is crucial. Such a system should exhibit characteristics observed in conventional culture systems that have used mouse embryonic fibroblast feeders for hPSC self renewal without the requirement of excessive supplementation with growth factors. To achieve this, we focused on the identification and characterization of extracellular matrix (ECM) substrates for hPSC propagation. ECM substrates derived from mouse and human fibroblasts were assessed for their ability to support self-renewal of hPSCs. Characterization of hPSCs on ECM-based substrates demonstrated maintenance of pluripotent characteristics based on a) high nuclear-cytoplasmic ratio b) immunocytochemical analyses for pluripotent markers (Alkaline phosphatase, AP, Octamer Binding Transcription Factor-4, OCT4 and Specific surface embryonic antigen-4, SSEA4) c) in vitro differentiation potential by embryoid body formation d) Real time RT-PCR analysis for pluripotent and germ-layer specific markers and e) karyotype analysis for chromosome number. Compositional characterization of the ECM substrates using proteomic analysis identified some of the major constituents of the matrix that might contribute to hPSC self-renewal. Based on results from the proteomic analysis, combinatorial ECM substrates were formulated using commercially available proteins and evaluated for applicability in hPSC propagation. Extensive characterization of hPSC propagated on the ECM substrates suggest that a combination of heparan sulfate proteoglycan and fibronectin was sufficient for the promoting hPSC sef-renewal. Finally, an in-direct co-culture system utilizing microporous membranes coated with acellular substrates and a physically separated feeder layer was developed as a microenvironment for hPSC propagation. Real time conditioning of the growth medium and an ECM-based substrate for hPSC adhesion provides a synergy of the biochemical and biophysical cues necessary for hPSC self-renewal. hPSCs cultured in this system demonstrated equivalent pluripotent characteristics as those propagated in conventional culture systems, and provided opportunities for scale up without cell mixing. Overall, these studies could prove to be useful in the development of humanized propagation systems for the production of stable hPSCs and its derivatives for research and therapeutic applications. substrates pluripotent stem cells Chemical Engineering Engineering
18	Evaluation of substrates for surface-enhanced Raman scattering Zhong, Muyang 15 August 2016 (has links) Surface-enhanced Raman scattering (SERS) has long been the interest of researchers in chemistry, physics and engineering, especially since the discovery that SERS can probe into the system down to the single molecule (SM) level. Despite the large number of publications regarding the fabrication of SERS substrates, it has been a challenge in the field to quantify the SERS signal and universally compare substrates. Traditionally, enhancement factor (EF) is used as an indicator of substrate quality, but the EF calculation is hugely dependent on the estimation of the surface coverage and other factors that are determined largely subjectively. Therefore, this thesis aims at discussing other parameters that can also be used to evaluate different substrates. Six different SERS substrates of Ag or Au nanoparticles of different sizes were fabricated by nanosphere lithography (NSL) and characterized by electron microscopy and UV-vis spectroscopy. SERS substrates were mapped for different concentrations of a probe molecule. Through subsequent baseline correction and principle component analysis (PCA), the "intensity" of individual spectrum was obtained and the shapes of intensity histograms of each substrate were acquired. Instead of calculating EF, five criteria (six quantification methods in total) were employed to comprehensively evaluate the six substrates. These were density of hot spots (characterized by the number of zero-intensity events), enhancement (represented by mean intensity), spatial variation (calculated by RSD of intensity), repeatability (realized by cross correlation) and histogram shape (quantified by skewness and kurtosis). These new methods provide insights to the understanding of the properties of SERS substrates in terms of hot spots. Different substrates may exhibit better performance in terms of one criterion but worse in terms of others. Those variations in performance can be explained by their surface morphology. These more elaborated methods are believed to provide a more comprehensive approach to evaluate and compare substrates than the traditional EF values. The thesis also paves the way for future study on SM-SERS and fabricating better SERS substrates. / Graduate surface-enhanced Raman scattering SERS substrates
19	Characterization of Arthrobacter Globiformis Aspartate Transcarbamylase Concentrations of Substrates Wright, Jackie 12 1900 (has links) This thesis consists of one major section with two subsections. The first subsection investigates the activity of Arthrobacter globiformis aspartate transcarbamylase's specific activity with increasing concentrations of the enzyme's substrate. Dihydroorotase (DHOase) activity was also measured with increasing concentrations of the substrate dihydroorotate. The second subsection collected data in order to classify the enzyme, resulting in a classification into the category of class A ATCases with bifunctional ATCase-DHOase complexes. The thesis provides evidence to broaden understanding of the ATCase and DHOase enzymes for members of the family that Arthrobacter belongs to. Arthrobacter globiformis aspartate transcarbamylase concentrations substrates
20	Microstructure and properties of copper thin films on silicon substrates Jain, Vibhor Vinodkumar 15 May 2009 (has links) Copper has become the metal of choice for metallization, owing to its high electrical and thermal conductivity, relatively higher melting temperature and correspondingly lower rate of diffusivity. Most of the current studies can get high strength copper thin films but on an expense of conductivity. This study proposes a technique to deposit high strength and high conductivity copper thin films on different silicon substrates at room temperature. Single crystal Cu (100) and Cu (111) have been grown on Si (100) and Si (110) substrates, respectively. Single crystal Cu (111) films have a high density of growth twins, oriented parallel to the substrate surface due to low twin boundary energy and a high deposition rate. The yield strengths of these twinned Cu films are much higher than that of bulk copper, with an electrical resistivity value close to that of bulk copper. X-ray diffraction, transmission electron microscopy and nanoindentation techniques were used to show that high density twins are sole reason for the increase in hardness of these thin films. The formation of growth twins and their roles in enhancing the mechanical strength of Cu films while maintaining low resistivity are discussed. Microstructure Copper thin film Silicon Substrates

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