Global ETD Search

231	UV laser patterning of silicone-based soft electrode grids Jakobsson, Maria January 2023 (has links) Roughly 123 million people worldwide are affected by conditions such as epilepsy, dementia, and cardiovascular diseases. Wearable electrodes are currently used to monitor these conditions short-term. Long-term monitoring would allow for predicting seizures and could be used as a preventive treatment. As opposed to the currently used electrodes, wearables that are intended for long-term use must be soft and flexible in order not to cause harm or discomfort for the user. The electrodes should also have high resolution, meaning that the electrode paths should be as narrow as possible without negatively affecting the performance of the electrode. In this thesis, soft and flexible electrode grids based on silicones are developed using UV laser patterning. Two different methods are evaluated: laser curing of silicones with the addition of a photoinitiator, and laser ablation of conductive composite. The results found in this thesis are that photocuring silicones gives a too low resolution to be useful for patterning soft electrode grids. UV laser ablation on the other hand showed high resolution while the electrodes retained stretchability. / <p>Examensarbetet är utfört vid Institutionen för teknik och naturvetenskap (ITN) vid Tekniska fakulteten, Linköpings universitet</p> Soft electrodes Wearable electrodes UV laser Laser ablation Laser curing Polydimethylsiloxane PDMS Silver flakes Teknisk biologi Teknisk biologi Medical Equipment Engineering Medicinsk apparatteknik
232	FABRICATION OF SOLVENT AND TEMPERATURE SENSITIVEPOLYMER BILAYER BENDING ACTUATORS Jian, Pei-Zhen 10 September 2019 (has links) No description available. Polymers Polymer Chemistry Materials Science
233	Study of Confinement and Sliding Friction of Fluids Using Sum Frequency Generation Spectroscopy Nanjundiah, Kumar January 2007 (has links) No description available. Physics, Optics Chemistry, Physical Chemistry, Polymer Engineering, Materials Science Physics, Condensed Matter sum frequency generation SFG PDMS sliding friction lubrication spectroscopy molecular structure confinement alkanes
234	Functionalization of In-plane Photonic Microcantilever Arrays for Biosensing Applications Ness, Stanley J. 29 October 2012 (has links) (PDF) Microcantilevers have been investigated as high sensitivity, label free biosensors for approximately 15 years. In nearly all cases, a thin gold film deposited on the microcantilevers is used as an intermediate attachment layer because of the convenience of thiol-gold chemistry. Unfortunately, this attachment chemistry can be unstable when used with complex sample media such as blood plasma. The Nordin group at BYU has recently developed an all-silicon in-plane photonic microcantilever (PMCL) technology to serve as a platform for label-free biosensing. It has the advantage of being readily scalable to simultaneous readout of many PMCLs in array format, and allows integration with polymer microfluidics to facilitate the introduction of biological samples and reagents. An essential processing step for the transformation of the PMCL into a practical biosensor is the ability to effectively immobilize active biological receptors directly on silicon PMCL surfaces such that ligand binding generates sufficient surface stress to cause measureable PMCL deflection. This dissertation presents the development of a method to functionalize the sensor surface of all-silicon in-plane photonic microcantilever (PMCL) arrays. This method employs a materials inkjet printer for non-contact jetting and a fluid that is custom designed for ink-jetting and biological applications with approximately 1 pL droplet size. The method facilitates the application of different receptors on select PMCLs with drop placement accuracy in the +/- 7.5 μm range. The functionalization fluid facilitates further processing using humidity control to achieve full coverage of only the PMCL's top surface and removal of dissolved salts to improve uniformity of receptor coverage and to prevent fouling of the sensor surface. Once a functionalization method was successfully developed, a series of experiments were performed to investigate the amount of surface stress that can be generated when receptors are immobilized directly to the silicon surface. In one series of experiments, a 4.8 μM streptavidin solution was used with biotin immobilized on multiple PMCLs to demonstrate adsorption-induced surface stress and concomitant deflection of the PMCL. The group observed ~ 15 nm PMCL deflection on average, with a corresponding surface stress of approximately 4 mN/m. These experiments yield the sensor response in real-time and employ a combination of multiple PMCLs functionalized as either sensors or unfunctionalized to serve as references. Investigation of various attachment chemistries is included, as well as a comparison with and without passivation of non-sensor surfaces. Investigated passivation strategies prevented ligand binding from generating a differential surface stress. Failure modes and physical mechanisms for adsorption-induced surface stress are discussed. Immobilization and passivation strategies for antibody-based biosensing are demonstrated with fluorescence microscopy and a corresponding PMCL sensing experiment using rabbit anti-goat F(ab') fragments as the receptors and Alex Fluor 488 labeled goat anti-rabbit IgGs as the ligand. While the results of these experiments remain inconclusive, suggestions for future research involving the PMCL sensor array are recommended. microcantilever inkjet functionalization in-plane photonic transduction photonic microcantilever biosensor PDMS microfluidics streptavidin biotin organosilane CVD antibody fragment immobilization F(ab') fragment adsorption-induced surface stress Electrical and Computer Engineering
235	INTER-PARTICLE LIQUID BRIDGES: A BUILDING BLOCK TO MODEL COMPLEX MIXING PHENOMENA Gopalkrishnan, Prasad 07 June 2004 (has links) No description available. Pendular liquid bridges Viscous force Glass PDMS Distinct Element Modeling (DEM) Dispersion/Aggregation mechanisms Cohesive or Adhesive failure Erosion or Rupture modes
236	Microfabrication Techniques for Printing on PDMS Elastomers for Antenna and Biomedical Applications Apaydin, Elif 30 September 2009 (has links) No description available. Engineering Microfabrication Techniques Flexible electronics PDMS elastomers Patterned Metal Printing Microtextured Surface Flexible Antennas Flexible Neural Microelectrode Array Brain Cortical Surface Recording Pt Electroplating Cu Electroplating
237	Siloxane-Based Reinforcement of Polysiloxanes: from Supramolecular Interactions to Nanoparticles Cashman, Mark Francis 01 October 2020 (has links) Polysiloxanes represent a unique class of synthetic polymers, employing a completely inorganic backbone structure comprised of repeating –(Si–O)n– 'siloxane' main chain linkages. This results in an assortment of diverse properties exclusive to the siloxane bond that clearly distinguish them from the –(C–C)n– backbone of purely organic polymers. Previous work has elucidated a methodology for fabricating flexible and elastic crosslinked poly(dimethyl siloxane) (PDMS) constructs with high Mc through a simultaneous crosslinking and chain-extension methodology. However, these constructs suffer the poor mechanical properties typical of lower molecular weight crosslinked siloxanes (e.g. modulus, tear strength, and strain at break). Filled PDMS networks represent another important class of elastomers in which fillers, namely silica and siloxane-based fillers, impart improved mechanical properties to otherwise weak PDMS networks. This work demonstrates that proper silicon-based reinforcing agent selection (e.g. siloxane-based MQ copolymer nanoparticles) and incorporation provides a synergistic enhancement to mechanical properties, whilst maintaining a low viscosity liquid composition, at high loading content, without the use of co-solvents or heating. Rheological analysis evaluates the viscosity while photorheology and photocalorimetry measurements evaluate rate and extent of curing of the various MQ-loaded formulations, demonstrating theoretical printability up to 40 wt% MQ copolymer nanoparticle incorporation. Dynamic mechanical analysis (DMA) and tensile testing evaluated thermomechanical and mechanical properties of the cured nanocomposites as a function of MQ loading content, demonstrating a 3-fold increase in ultimate stress at 50 wt% MQ copolymer nanoparticle incorporation. VP AM of the 40 wt% MQ-loaded, photo-active PDMS formulation demonstrates facile amenability of photo-active PDMS formulations with high MQ-loading content to 3D printing processes with promising results. PDMS polyureas represent an important class of elastomers with unique properties derived from the synergy between the nonpolar nature, unusual flexibility, and low glass transition temperature (Tg) afforded by the backbone siloxane linkages (-Si-O)n- of PDMS and the exceptional hydrogen bond ordering and strength evoked by the bidentate hydrogen bonding of urea. The work herein presents an improved melt polycondensation synthetic methodology, which strategically harnesses the spontaneous pyrolytic degradation of urea to afford a series of PDMS polyureas via reactions at high temperatures in the presence of telechelic amine-terminated oligomeric poly(dimethyl siloxane) (PDMS1.6k-NH2) and optional 1,3-bis(3-aminopropyl)tetramethyldisiloxane (BATS) chain extender. This melt polycondensation approach uniquely circumvents the accustomed prerequisite of isocyanate monomer, solvent, and metal catalysts to afford isocyanate-free PDMS polyureas using bio-derived urea with the only reaction byproduct being ammonia, a fundamental raw ingredient for agricultural and industrial products. As professed above, reinforcement of polysiloxane materials is ascertained via the incorporation of reinforcing fillers or nanoparticles (typically fumed silica) or blocky or segmented development of polymer chains eliciting microphase separation, in order to cajole the elongation potential of polysiloxanes. Herein, a facile approach is detailed towards the synergistic fortification of PDMS-based materials through a collaborative effort between both primary methods of polysiloxane reinforcement. A novel one-pot methodology towards the facile, in situ incorporation of siloxane-based MQ copolymer nanoparticles into segmented PDMS polyureas to afford MQ-loaded thermoplastic and thermoplastic elastomer PDMS polyureas is detailed. The isocyanate-free melt polycondensation achieves visible melt dispersibility of MQ copolymer nanoparticles (good optical clarity) and affords segmented PDMS polyureas while in the presence of MQ nanoparticles, up to 40 wt% MQ, avoiding post-polymerization solvent based mixing, the only other reported alternative. Incorporation of MQ copolymer nanoparticles into segmented PDMS polyureas provides significant enhancements to modulus and ultimate stress properties: results resemble traditional filler effects and are contrary to previous studies and works discussed in Chapter 2 implementing MQ copolymer nanoparticles into chemically-crosslinked PDMS networks. In situ MQ-loaded, isocyanate-free, segmented PDMS polyureas remain compression moldable, affording transparent, free-standing films. / Master of Science / Polysiloxanes, also referred to as 'silicones' encompass a unique and important class of polymers harboring an inorganic backbone. Polysiloxanes, especially poly(dimethyl siloxane) (PDMS) the flagship polymer of the family, observe widespread utilization throughout industry and academia thanks to a plethora of desirable properties such as their incredible elongation potential, stability to irradiation, and facile chemical tunability. A major complication with the utilization of polysiloxanes for mechanical purposes is their poor resistance to defect propagation and material failure. As a result polysiloxane materials ubiquitously observe reinforcement in some fashion: reinforcement is achieved either through the physical or chemical incorporation of a reinforcing agent, such as fumed silica, or through the implementation of a chemical functionality that facilitates reinforcement via phase separation and strong associative properties, such as hydrogen bonding. This research tackles polysiloxane reinforcement via both of these strategies. Facile chemical modification permits the construction PDMS polymer chains that incorporate hydrogen bonding motifs, which phase separate to afford hydrogen bond-reinforced phases that instill vast improvements to elastic behavior, mechanical and elongation properties, and upper-use temperature. Novel nanocomposite formulation through the incorporation of MQ nanoparticles (which observe widespread usage in cosmetics) facilitate further routes toward improved mechanical and elongation properties. Furthermore, with growing interest in additive manufacturing strategies, which permit the construction of complex geometries via an additive approach (as opposed to conventional manufacturing processes, which require subtractive approaches and are limited in geometric complexity), great interest lies in the capability to additively manufacture polysiloxane-based materials. This work also illustrates the development of an MQ-reinforced polysiloxane system that is amenable to conventional vat photopolymerization additive manufacturing: chemical modification of PDMS polymer chains permits the installation of UV-activatable crosslinking motifs, allowing solid geometries to be constructed from a liquid precursor formulation. Siloxane polysiloxane poly(dimethyl siloxane) (PDMS) MQ copolymer nanoparticle vat photopolymerization (VP) additive manufacturing (AM) 3D printing (3DP) chain extender microphase separation
238	Microssistemas eletroforéticos em materiais poliméricos de duplo canal com detecção amperométrica / Electrophoretic microsystems in polymeric materials dual channel with amperometric detection Santos, Diógenes Meneses dos 25 May 2014 (has links) Electrophoretic microsystems (EM) are powerful tools for the separation of species of microsystems analyzes which can easily be combined with electrochemical detection (ECD) and therefore making it ideal for a method of detection. However, the influence of high voltage at the working electrode used for the separation is a problem to be overcome due to the increased signal/noise ratio and possible damage of the electrode and/or the potentiostat. Thus, it was proposed in this thesis one EM hybrid PDMS / glass configuration with dual-channel potentiostat coupled to an electrically isolated in order to minimize the influence of high potential in the separation channel and improve the separation efficiency of the species and subsequently, improve detection limits. The EM contains two separate parallel channels 200 microns and a channel separation and another reference, and each containing a platinum electrode 15 or 50 μm placed about 1 to 4 μm in the channel. An electrode served as the working electrode, positioned in the separation channel, and another electrode as reference electrode, placed in the reference channel. This configuration associated with the electrically isolated potentiostat allowed the amperometric signals were measured without any change or potential interference arising from the high voltage applied separation. Aiming to evaluate the effectiveness of the methodology proposed in this thesis, samples nitrite, tyrosine and peroxynitrite (reactive nitrogen species – RNS), hydrogen peroxide (reactive oxygen species – ROS), ascorbic acid, glutathione and cysteine were injected into the channel containing the working electrode, while simultaneously boric acid buffer pH 11 containing TTAB was injected into the reference channel containing the reference electrode. From this configuration, we obtained a significant reduction in noise level (about 0.94 pA) and a relative improvement in the resolution ratified by electropherograms, compared with using single channel configuration. The limits of detection (LOD) for the chemical species mentioned above were 0.58 μM, 0.14 μM, 0.75 μM, 0.21 μM, 0.82 μM, was not obtained for cysteine and 1.63 μM, respectively. The efficiency can also be seen by analyzing nitrite performed on samples of perfusate blood of sheeps and rats, where have been detected a concentration of 68.05 μM and 22.04 μM, respectively, by the proposed method. It was also proposed in this thesis, microfabrication and evaluation of a PMMA electrophoretic microsystem with single channel configuration coupled to a base made of the same material to fix the microchip with electrochemical detection using a carbon paste electrode. The purpose of the construction of the base was to obtain, by fixing, reproducibility of events. And the microfabrication of PMMA EM aimed the viability of its use in analysis perspective as having the lowest cost per unit made due to the use of CO2 laser for microfabrication, which has a value considerably lower, compared with photolithographic processes. The evaluation of this system was performed through the analysis standards of serotonin and acetaminophen, which proved that the microfabrication of this system showed good reproducibility and repeatability of events, making it viable processing. / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Os microssistemas eletroforéticos (MSE) são ferramentas poderosas para a separação de espécies em microssistemas de análises, onde pode ser facilmente combinada com detecção eletroquímica (DEQ) e tornando-se, portanto, um método de detecção ideal. No entanto, a influência da alta tensão no eletrodo de trabalho utilizada para a separação é um problema a ser contornado devido o aumento da relação sinal/ruído e possíveis danificações do eletrodo e/ou do potenciostato. Assim, foi proposto nesta tese um MSE híbrido de PDMS/vidro com configuração de duplo-canal acoplado a um potenciostato eletricamente isolado com objetivo de minimizar a influência do elevado potencial no canal de separação e melhorar a eficiência de separação das espécies e, subsequentemente, melhorar os limites de detecção. O MSE contém dois canais paralelos separados 200 μm, sendo um canal de separação e outro de referência, e cada um deles contendo um eletrodo de platina de 15 ou 50 μm colocados cerca de 1 a 4 μm dentro do canal. Um eletrodo serviu como eletrodo de trabalho, posicionado no canal de separação, e o outro eletrodo como eletrodo de referência, posicionado no canal de referência. Essa configuração associado ao potenciostato eletricamente isolado permitiu que os sinais amperométricos fossem medidos sem qualquer mudança de potencial ou de interferência oriunda da alta tensão de separação aplicada. Objetivando avaliar a eficiência da metodologia proposta nessa tese, amostras de nitrito e peroxinitrito (espécies reativas de nitrogênio – ERN), tirosina, peróxido de hidrogênio (espécie reativa de oxigênio – ERO), ácido ascórbico, glutationa e cisteína foram injetadas no canal contendo o eletrodo de trabalho, enquanto que simultaneamente o tampão de ácido bórico contendo TTAB pH 11 foi injetado no canal de referência contendo o eletrodo de referência. A partir desta configuração, obteve-se uma significativa diminuição no nível de ruído (cerca de 0,94 pA) e uma relativa melhora na resolução ratificadas pelos eletroferogramas, se comparado com a configuração que utiliza canal único. Os limites de detecção (LOD) para as espécies químicas supracitados foram de 0,58 μM, 0,14 μM, 0,75 μM, 0,21 μM, 0,82 μM, não foi obtida para a cisteína, e 1,63 μM, respectivamente. A eficiência também pode ser vista através das análises de nitrito realizadas em amostras de perfusato de sangue de ovelhas e ratos, onde foram detectados uma concentração de 68,05 μM e 22,04 μM, respectivamente, através da metodologia proposta. Foi proposto também nessa tese, a microfabricação e avaliação de um microssistema eletroforético de PMMA com configuração de canal único acoplado a uma base feita do mesmo material para fixar o microchip, com detecção eletroquímica usando eletrodo de pasta de carbono. O objetivo da construção da base foi obter, através da fixação, reprodutibilidade de eventos. E a microfabricação do MSE de PMMA objetivou a viabilidade do seu uso em análises tendo como perspectiva o baixo custo por unidade confeccionada devido ao uso de laser de CO2 para a microfabricação, o qual possui um valor agregado consideravelmente menor, se comparado com os processos fotolitográficos. A avaliação desse sistema foi feita através das análises de padrões de serotonina e acetaminofeno, onde comprovou-se que a microfabricação desse sistema apresentou boa reprodutibilidade e repetitividade de eventos, tornando-se viável o seu processamento. Eletroforese em microchip Detecção eletroquímica Espécies reativas de oxigênio (ERO) Espécies reativas de nitrogênio (ERN) Microfluídicos de PMMA Microchip electrophoresis Electrochemical detection Reactive oxygen species (ROS) Reactive Nitrogen Species (RNS) Microfluidics of PMMA
239	Investigation of membrane fusion as a function of lateral membrane tension / Investigation of membrane fusion as a function of lateral membrane tension Kliesch, Torben-Tobias 07 June 2017 (has links) No description available. 571.4 membrane fusion membrane tension SNARE proteins adhered giant unilamellar vesicles vesicle fusion supported lipid bilayers stretching of lipid membranes membrane area dilatation fluorescence microscopy neuronal membrane fusion milli-fluidic device PDMS lateral membrane tension anisotropic dilatation of PDMS Biologie (PPN619462639)
240	Applications of microfluidic chips in optical manipulation & photoporation Marchington, Robert F. January 2010 (has links) Integration and miniaturisation in electronics has undoubtedly revolutionised the modern world. In biotechnology, emerging lab-on-a-chip (LOC) methodologies promise all-integrated laboratory processes, to perform complete biochemical or medical synthesis and analysis encapsulated on small microchips. The integration of electrical, optical and physical sensors, and control devices, with fluid handling, is creating a new class of functional chip-based systems. Scaled down onto a chip, reagent and sample consumption is reduced, point-of-care or in-the-field usage is enabled through portability, costs are reduced, automation increases the ease of use, and favourable scaling laws can be exploited, such as improved fluid control. The capacity to manipulate single cells on-chip has applications across the life sciences, in biotechnology, pharmacology, medical diagnostics and drug discovery. This thesis explores multiple applications of optical manipulation within microfluidic chips. Used in combination with microfluidic systems, optics adds powerful functionalities to emerging LOC technologies. These include particle management such as immobilising, sorting, concentrating, and transportation of cell-sized objects, along with sensing, spectroscopic interrogation, and cell treatment. The work in this thesis brings several key applications of optical techniques for manipulating and porating cell-sized microscopic particles to within microfluidic chips. The fields of optical trapping, optical tweezers and optical sorting are reviewed in the context of lab-on-a-chip application, and the physics of the laminar fluid flow exhibited at this size scale is detailed. Microfluidic chip fabrication methods are presented, including a robust method for the introduction of optical fibres for laser beam delivery, which is demonstrated in a dual-beam optical trap chip and in optical chromatography using photonic crystal fibre. The use of a total internal reflection microscope objective lens is utilised in a novel demonstration of propelling particles within fluid flow. The size and refractive index dependency is modelled and experimentally characterised, before presenting continuous passive optical sorting of microparticles based on these intrinsic optical properties, in a microfluidic chip. Finally, a microfluidic system is utilised in the delivery of mammalian cells to a focused femtosecond laser beam for continuous, high throughput photoporation. The optical injection efficiency of inserting a fluorescent dye is determined and the cell viability is evaluated. This could form the basis for ultra-high throughput, efficient transfection of cells, with the advantages of single cell treatment and unrivalled viability using this optical technique.

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