Global ETD Search

201	Development of perfluoroelastomer-based low-sorption microfluidic devices for drug metabolism and toxicity studies / 薬物代謝・毒性研究のための過フッ素化エラストマー製低収着マイクロ流体デバイスの開発 Wang, Mengyang 23 March 2023 (has links) 京都大学 / 新制・課程博士 / 博士(薬科学) / 甲第24548号 / 薬科博第165号 / 新制\|\|薬科\|\|18(附属図書館) / 京都大学大学院薬学研究科薬科学専攻 / (主査)教授山下富義, 教授髙倉喜信, 教授寺田智祐 / 学位規則第4条第1項該当 / Doctor of Pharmaceutical Sciences / Kyoto University / DFAM perfluoropolyether elastomer microfluidic device drug metabolism drug toxicity bioavailability 499.3
202	PRECISION TECHNOLOGIES FOR LONG-TERM IMAGING OF STOCHASTIC ORGANISMAL DYNAMICS Karl Ferdinand Ziegler (18421836) 23 April 2024 (has links) <p dir="ltr">The goal of this dissertation is to develop precision technologies to facilitate establishing, in the context of stochastic organismal dynamics, organizational principles that govern basic regulatory processes in living systems. We focus on biological timekeeping, the interplay of biological lengths and timescales, and strategies governing the control of rapid vs. precise adaptation to changing phenomena supporting complex phenotypes. In particular, individual cells of unicellular organisms respond with remarkable precision and plasticity in their growth and division to changes in their noisy environments. Cells rely on scalable timekeepers and quantitative tradeoffs to accomplish this precision. In this dissertation we will address longstanding open questions in cell biology, such as: How does an individual cell maintain size homeostasis across multigenerational dynamics, as it repeatedly grows and divides? How does an organism adapt its growth rate to reflect changing environmental conditions? The development of understanding of systems-level organizational principles in a controlled experimental system in turn advances our general ability to predict and control stochastic organismal dynamics, and thus develop functional synthetic adaptive systems.</p> Biomechanical engineering stochastic dynamic microfluidic mother machine SChemostat
203	Development of a Biosensor to Predict Activated Sludge Deflocculation, and the Link Between Chlorination and Potassium Efflux Wimmer, Robert Francis 03 April 2002 (has links) In an effort to provide wastewater treatment operators with the capability to be proactive in assessing and solving deflocculation events, this study has tested the components of a biosensor to predict deflocculation and investigated the mechanistic cause of deflocculation relating to chlorination of activated sludge cultures. In order to effectively manage upset events, it is necessary to know the source of an upset and the causative mechanism that the source initiates. The Glutathione-gated potassium efflux (GGKE)induced activated sludge deflocculation biosensor incorporates novel microtechnology with a whole cell biological element to predict deflocculation from electrophilic sources. This sensor utilizes microfluidic channels to conduct influent wastewater across a biofilm of Eschericia coli K 12 and monitors the bacterial response to the influent. The bacterial response, which is efflux of K+ ion from the cytoplasm, is monitored with a fluorescence-based sensor called an optode. The components of the system satisfy the project requirements, which include minimal expense (both operation and manufacture), on-line capability and minimal maintenance. The research conducted to date demonstrates the ability of the components of the biosensor to fulfill the design requirements. The optode K+ detector successfully measured an increase in soluble K+ following the exposure of E. coli K-12 to the electrophile N ethyl malemide. The manufacture of the microfluidic device has been completed and the device has demonstrated the ability to conduct influent under negative pressure across an established biofilm with the optode in place. The establishment of a biofilm under expected hydrodynamic conditions has also been completed. Future research efforts will include integrating the components of the biosensor into a working prototype that will be capable monitoring the reaction of bacteria to the presence of electrophilic compounds in wastewater. Sensors of this nature will provide operators with the early warning necessary to be proactive against toxic upsets rather than reactive. The knowledge needed to create a biosensor resides in the identification of bacterial response mechanisms that cause upset events in wastewater treatment facilities. The biosensor that has been developed relies on the discovery of the link between electrophile-induced GGKE and activated sludge deflocculation. Research has been concluded, which expands the role of GGKE and activated sludge deflocculation to include chlorine-induced GGKE. Through a series of laboratory-scale reactors, a relationship has been established between chlorine addition to control filamentous bulking, increased soluble K+ levels and an increase in effluent suspended solids . The results demonstrate that the addition of chlorine to control filamentous bulking may elicit the GGKE mechanism, initiating activated sludge deflocculation, similar to observations of chlorination at full-scale activated sludge wastewater treatment facilities. Establishing a mechanistic cause of deflocculation related to chlorination will permit operators to apply chlorine in a manner that may avoid deflocculation, rather than reacting to deflocculation after it has occurred. / Master of Science biosensor potassium efflux chlorine microfluidic activated sludge glutathione
204	Multiphysics Modeling Of Devices For Whole Organ Healthcare Applications Tong, Yuxin 12 June 2017 (has links) In order to fully understand the functionality of conformal devices, it is critical to develop computational models built from engineered models of 3-dimensional objects. This thesis established a scanning procedure to engineering 3D digital model for whole organs, known as template engineering. The resultant scanning data enabled designing, manufacturing, and modeling of novel organ healthcare devices. Specifically, we applied template engineering and structured-light scanning techniques to capture the 3D topographical information for whole organ systems. Sequentially, we developed multiphysics models for understanding the device functionality, including the function of devices for microfluidic interface and whole organ mechanical stabilization. / Master of Science / This study facilitated the development of computational models for whole organ healthcare devices. In order to develop a fundamental understanding of conforming biomedical devices for kidney assessment computational models were developed that simulate the interaction between the device and the soft organ. In this work, we generated a digital reconstruction of a porcine kidney model by surface scanning techniques that served as the domain two types of organ-devices interaction simulations: 1) organ-fluid contact problems and 2) organ-solid contact problems. This study proved that multiphysics modeling offers the potential toward the design and modeling of next-generation biomedical devices for whole organ healthcare. multiphysics modeling conformal microfluidic conformal printing organ assessment
205	Pillar/Perfusion Plates for Miniature Human Tissue Culture and Predictive Compound Screening Kang, Sooyeon 05 1900 (has links) Human organoids have potential to revolutionize in vitro disease modeling by providing multicellular architecture and functional that are similar to those in vivo. Nonetheless, organoid-based, high-throughput screening (HTS) of compounds is challenged by lack of easy-to-use fluidic systems that are compatible with relatively large organoids. Therefore, we first fabricated a pillar plate, which was coupled with a complementary deep well plate and a perfusion well plate for static and dynamic culture via injection molding. We established various cell loading methods in hydrogels on the pillar plate. In addition, we investigated the effect of flow on the necrotic core of spheroids in the pillar/perfusion plate. Finally, we developed microarray three-dimensional (3D) bioprinting technology using the pillar and perfusion plates for human organoid culture and analysis. High-precision, high-throughput stem cell printing and encapsulation techniques were demonstrated on a pillar plate, which was coupled with a complementary deep well plate and a perfusion well plate for static and dynamic organoid culture. Bioprinted cells and spheroids in hydrogels were differentiated into organoids for in situ functional assays. The pillar/perfusion plates are compatible with standard 384-well plates and HTS equipment, and thus may be easily adopted in current drug discovery efforts. Microfluidic system Pillar/Perfusion Plate Organoid culture Engineering, Biomedical
206	Engineering amphiphilic fabrics for microfluidic applications Owens, Tracie LeeAnne 14 November 2011 (has links) Woven textile fabrics were designed and constructed from hydrophilic and hydrophobic spun yarns to give planar substrates containing amphiphilic microchannels with defined orientations and locations. Polypropylene fibers were spun to give hydrophobic yarns, and the hydrophilic yarns were spun from a poly(ethylene terephthalate) copolyester. Water wicking rates into the fabrics were measured by video microscopy and longitudinal wicking tests from single drops and from reservoirs. Intra-yarn microchannels in the hydrophilic polyester yarns were shown to selectively transport aqueous fluids, with the flow path governed by the placement of the hydrophilic yarns in the fabric. Simultaneous wicking of an aqueous and hydrocarbon fluid into the hydrophilic and hydrophobic microchannels of an amphiphilic fabric was successfully demonstrated. The high degree of interfacial contact and micron-scale diffusion lengths of such co-flowing immiscible fluid streams inside amphiphilic fabrics suggest potential applications as highly scalable and affordable microcontactors for industrial liquid-liquid extractions. The efficiency of liquid-liquid extractions carried out with the amphiphilic fabrics was evaluated. Solvent extraction efficiencies were shown to reach up to ~98%. Solvent extraction Microfluidic Liquid-liquid extraction Thread Fabric Wicking Microfluidics Microfluidic devices Solvent extraction Chemistry, Analytic Chemistry, Analytic Technique
207	Détection de l’ADN par spectrométrie de diffusion Raman exaltée de surface couplée à la microfluidique / DNA detection by surface enhanced Raman spectroscopy coupled with microfluidic Prado, Enora 10 November 2011 (has links) Ce travail présente une méthode originale de détection et de quantification, sans étape de marquage, de la proportion de bases libres contenues dans des acides nucléiques. La spectrométrie de diffusion Raman exaltée de surface (DRES ou SERS en anglais) nous a permis d’obtenir la signature spectrale spécifique des nucléotides caractéristiques des ARN (adénosine, cytosine, guanosine et uridine), en utilisant des colloïdes d’argent comme substrat-DRES et des ajouts de MgCl2 comme agent d’agrégation. Les conditions de détection ont été optimisées pour établir un protocole de quantification de la proportion des nucléobases non-appariées par spectrométrie DRES. Les limites de détection obtenues sont de l’ordre de quelques dizaines de picomoles. L’amélioration de la reproductibilité des mesures par spectrométrie DRES passe par le contrôle précis des temps de réaction (adsorption et agrégation), qui peut être contrôlé grâce à l’utilisation de plateformes microfluidiques adaptées. Nous avons mis en œuvre deux types de plateformes microfluidiques, l’une basée sur des écoulements monophasiques et l’autre sur la génération de gouttes. Les espèces à analyser sont contenus dans les gouttes, permettant la détection in situ par spectrométrie DRES des divers nucléotides. / This work deals with the development of an original label-free method for free bases proportions detection and quantification of nucleic acids. The surface enhanced Raman spectroscopy (SERS) allowed obtaining the specific spectral signature of characteristic nucleotides of RNA (adenosine, cytosine, guanosine and uridine), using silver colloids as SERS substrate and MgCl2 addition as aggregating agent. Then, the condition detection have optimizing to establish a label-free quantification protocol of free nucleobases proportion by SERS spectroscopy. The detection limits obtained are order of few picomoles. The reproducibility improvement of SERS detection requires the precise control of time reaction (adsorption and aggregation), which could be control thanks to microfluidic chips use. We have implemented two different microfluidic chips, one based on single-phase flows and one other based on droplets generation. The analyzed species are containing in droplets, allowing in situ detection by spectroscopy SERS of various nucleotides. Microfluidique Détection d’ARN sans marquage Adn Arn Acides nucléiques Surface enhanced Raman Scattering Microfluidic Single-phase microfluidic Droplet generation microfluidic Label-free detection Dna Rna Nucleic acid
208	Microfluidic Device for Phenotype-Dependent Cell Agility Differentiation and Corresponding Device Sensory Implementation Starr, Kameron D. January 2017 (has links) No description available. Biomedical Engineering Biomechanics EMT MET CTC Metastasis Cell Agility Agility Microfluidic Microfluidic Device Migration Sensor Biosensor Microfluidic Sensor Biomechanical MDA-MB-468 Hs 578T Prototype Cell Sensor Single Cell Single Cell Analysis Cell Analysis Cancer
209	Integration methods for enhanced trapping and spectroscopy in optofluidics Ashok, Praveen Cheriyan January 2011 (has links) “Lab on a Chip” technologies have revolutionized the field of bio-chemical analytics. The crucial role of optical techniques in this revolution resulted in the emergence of a field by itself, which is popularly termed as “optofluidics”. The miniaturization and integration of the optical parts in the majority of optofluidic devices however still remains a technical challenge. The works described in this thesis focuses on developing integration methods to combine various optical techniques with microfluidics in an alignment-free geometry, which could lead to the development of portable analytical devices, suitable for field applications. The integration approach was applied to implement an alignment-free optofluidic chip for optical chromatography; a passive optical fractionation technique fractionation for cells or colloids. This system was realized by embedding large mode area photonic crystal fiber into a microfluidic chip to achieve on-chip laser beam delivery. Another study on passive sorting envisages an optofluidic device for passive sorting of cells using an optical potential energy landscape, generated using an acousto-optic deflector based optical trapping system. On the analytical side, an optofluidic chip with fiber based microfluidic Raman spectroscopy was realized for bio-chemical analysis. A completely alignment-free optofluidic device was realized for rapid bio-chemical analysis in the first generation by embedding a novel split Raman probe into a microfluidic chip. The second generation development of this approach enabled further miniaturization into true microfluidic dimensions through a technique, termed Waveguide Confined Raman Spectroscopy (WCRS). The abilities of WCRS for online process monitoring in a microreactor and for probing microdroplets were explored. Further enhanced detection sensitivity of WCRS with the implementation of wavelength modulation based fluorescent suppression technique was demonstrated. WCRS based microfluidic devices can be an optofluidic analogue to fiber Raman probes when it comes to bio-chemical analysis. This allows faster chemical analysis with reduced required sample volume, without any special sample preparation stage which was demonstrated by analyzing and classifying various brands of Scotch whiskies using this device. The results from this study also show that, along with Raman spectroscopic information, WCRS picks up the fluorescence information as well, which might enhance the classification efficiency. A novel microfabrication method for fabricating polymer microlensed fibers is also discussed. The microlensed fiber, fabricated with this technique, was combined with a microfluidic gene delivery system to achieve an integrated system for optical transfection with localized gene delivery. 535
210	Development of Ready-to-Use Biosensors for Diagnostics and Biosensing Jahanshahi-Anbuhi, Sana 06 1900 (has links) Ideally, every person in the world should have access to a safe and clean water supply; if not all sources of water are clean and safe, at the very least, an effective method to detect water contamination should be readily available. An effective detection method should not only be sensitive, rapid, robust, and affordable, but, ideally, it should also be equipment-free and easy to transport and deliver to the end-users. The main goal of this project is to develop a variety of bits and pieces of bioassay systems, with a particular focus on paper-based bioactive devices in order to provide portable and ready-to-use biosensors which can be useable by anyone anywhere around the world without requiring formal training. According to the World Health Organization (WHO), 76,000 people each year die in India alone because of pesticide poisoning. Long term exposure to organophosphate pesticides is known to have adverse effects on neurological function and can lead to Alzheimer's Disease, Attention Deficit Hyperactivity Disorder (ADHD), and reduced Intelligence Quotient (IQ). The likelihood of long term exposure to pesticides is heightened in developing countries, so a reliable and inexpensive pesticide sensor is a much-needed device in the developing world. To address this need, this project reports on the development of a fully-automated bioactive paper-based sensor for the detection of organophosphate pesticides. In the proposed biosensor, two innovations were implemented to achieve a full-automated format for the pesticide sensor: (I) First is a PUMP ON A PAPER (Jahanshahi-Anbuhi et al., LOC, 2012) that increases the flow rate of fluids within paper-based microfluidic analytical devices and sequentially brings two separate liquid streams to the enzyme test zone on the paper sensor, and (II) the second innovation is a PIPETTE ON A PAPER (Jahanshahi-Anbuhi et al., LOC, 2014) that involved the creation of a pullulan (a natural non-ionic polysaccharide) temporary bridge-system to transfer a known amount of solution to the sensing zone that, gives the enzyme zone a chance to dry and accept the substrate solution from the slow channel after a fixed period of time. This proposed format results in a simplified assay that detects the presence of pesticides automatically without any further manipulation from the user. However, the shelf life of this assay kit is challenging due to instability of both enzyme (AChE) and substrate (IDA) at room temperature. AChE loses its enzymatic activity when stored at room temperature and IDA becomes oxidized quickly. This problem is not unique to these two bio reagents, however; almost all bioassays which use bio-reagents (such as enzymes and small-molecular substrates) are unstable to varying degrees and require special shipping and storage. The instability of these molecules can arise from either thermal denaturation or chemical modification, such as oxidation or hydrolysis. Because of these issues, they often have to be shipped on dry ice with special packaging, which is costly. The cost of maintaining a cold chain for distributing bio-reagents accounts for up to 80% of the cost. Aside from the cost, these reagents also have to be stored in bulk in refrigerators or freezers to minimize the loss of activity, but they must be thawed and aliquoted for their intended tests. Repeated freezing and thawing can result in a significant loss of activity, which often leads to less reliable test results. These issues make running such assays in resource-limited settings a significant challenge. There is, therefore, an urgent need for an assay system with stable reagents that is easy to use, simple to read, inexpensive, and that includes a method for the long-term stabilization of enzymes and other unstable reagents in pre-measured quantities. To overcome to all these issues, pullulan is utilized for the development of pill-based-biosensors. Pullulan dissolves quickly in aqueous solutions and shows very high oxygen barrier properties in its film form. Considering the unique properties of pullulan, it is hypothesized that pullulan may be suitable for producing assay pills with encapsulated enzymes or other unstable molecules and may provide a simplified platform for carrying out bioassays in resource-limited settings. The application of these pill-based-biosensors is shown via the entrapment of AChE and IDA for the creation of an assay kit that can detect organophosphate pesticides (Jahanshahi-Anbuhi et al., Angew. Chem., 2014). Moreover, this thesis reports on the stabilization of highly unstable firefly luciferase for the detection of microorganisms and, more particularly, ATP. Through the use of pullulan, this thesis demonstrates that both the enzyme and the substrate can be protected, immobilized, and stabilized at room temperature, instead of the existing storage methods, which require temperatures <-20˚C. This innovation allows for a more convenient method of shipping the bioassay kits around the world without any extra care. Furthermore, pullulan-based films are utilized for the development of a method for controlled multidirectional flow within paper-based biosensors. This method provides the possibility of trapping labile and volatile reagents and stabilizing them by forming thin films with pullulan. The trapped reagents within pullulan films can be strategically stacked and assembled on a paper strip in different directions. Furthermore, should the need arise, these reagents can be released and delivered sequentially or simultaneously in both vertical and lateral directions through the paper. The application of this method is shown for: (I) creation of "ready-to-use" assay kit for the detection of Escherichia coli (E. Coli). This assay kit has the step of cell lysing and proceeds automatically to the step in which enzymes react. The second application (II) shows the trapping of Simon’s reagents, which is widely used for methamphetamine detection. Overall, these unique fabrication techniques can be widely used for the preparation of highly stable, ready-to-use, and user-friendly biosensors. We are currently working on the detection of other contaminants such as heavy metals, and we are starting on vaccine stabilization and delivery, which would have a tremendous impact for society. / Dissertation / Doctor of Engineering (DEng) Biosensor Microfluidic Bio-active Paper Paper Based Microfluidic Devices Pullulan Pill Based Assay Reagent Release Enzyme Stabilization Organophosphate Pesticide E. coli Luciferase Luminescent Lab on Pills Pullulan Tablet Pullulan Capsule

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