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Detection of Biomolecules Using Volume-Amplified Magnetic NanobeadsZardán Gómez de la Torre, Teresa January 2012 (has links)
This thesis describes a new approach to biomolecular analysis, called the volume-amplified magnetic nanobead detection assay (VAM-DNA). It is a sensitive, specific magnetic bioassay that offers a potential platform for the development of low-cost, easy-to-use diagnostic devices. The VAM-NDA consists of three basic steps: biomolecular target recognition, enzymatic amplification of the probe-target complex using the rolling circle amplification (RCA) technique, and addition of target complementary probe-tagged magnetic nanobeads which exhibit Brownian relaxation behavior. Target detection is demonstrated by measuring the frequency-dependent complex magnetization of the magnetic beads. The binding of the RCA products (target DNA-sequence coils) to the bead surface causes a dramatic increase in the bead size, corresponding essentially to the size of the DNA coil (typically around one micrometer). This causes a decrease in the Brownian relaxation frequency, since it is inversely proportional to the hydrodynamic size of the beads. The concentration of the DNA coils is monitored by measuring the decrease in amplitude of the Brownian relaxation peaks of free beads. The parameters oligonucleotide surface coverage, bead concentration, bead size and RCA times were investigated in this thesis to characterize features of the assay. It was found that all of these parameters affect the outcome and efficiency of the assay. The possibility of implementing the assay on a portable, highly sensitive AC susceptometer platform was also investigated. The performance of the assay under these circumstances was compared with that using a superconducting quantum interference device (SQUID); the sensitivity of the assay was similar for both platforms. It is concluded that, the VAM-NDA opens up the possibility to perform biomolecular detection in point-of-care and outpatient settings on portable platforms similar to the one tested in this thesis. Finally, the VAM-NDA was used to detect Escherichia coli bacteria and the spores of Bacillus globigii, the non-pathogenic simulant of Bacillus anthracis. A limit of detection of at least 50 bacteria or spores was achieved. This shows that the assay has great potential for sensitive detection of biomolecules in both environmental and biomedical applications.
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Nanobilles de quantum dots fluorescents pour la détection biomoléculaire / Quantum dot-based nanobeads functionalized for biodetectionDembele, Fatimata 06 October 2017 (has links)
Les propriétés des quantum dots (QDs) en font des sondes adaptées à la reconnaissance moléculaire. Leur pic d’émission en fluorescence est très étroit et ajustable, tandis que la section efficace de leur spectre d’absorption est très large. En outre, ils sont très brillants et résistent mieux au photoblanchiment que les colorants organiques conventionnels.Notre objectif a été de concevoir un nouveau type de sondes fluorescentes pour une détection rapide à l’échelle de la molécule unique. L’utilisation d’agrégats contenant plusieurs milliers de QDs, plutôt que celle de QDs individuels, permet d’accroître le signal de fluorescence et de simplifier les modalités de détection. La morphologie et la chimie de surface des premiers agrégats préparés n’ont pas pu être contrôlées en les recouvrant avec des molécules de surfactants courts ou une couche de polymère en solution aqueuse. La stratégie centrale de ce manuscrit a permis d’assembler les QDs en nanobilles (NBs) monodisperses de quelques centaines de nanomètres de diamètre, encapsulées dans une couche de silice Stöber. Leur stabilité colloïdale et leur photostabilité ont ainsi été conservées. Un nouveau type d’hybride polymère-silane a été greffé sur la silice. Il présente des chaînes zwittérioniques, garantissant la solubilité en milieu aqueux et une adsorption non spécifique minimale, ainsi que des fonctions réactives pour la bioconjugaison. La réactivité de NBs fonctionnalisées par de la streptavidine avec des billes commerciales biotinylées a été démontrée. Nos résultats préliminaires ont également montré que les NBs peuvent être intégrées dans un dispositif microfluidique pour être comptées individuellement. / Using nanotechnology for molecular diagnostics holds many advantages e.g. an improvement in the simplicity and the sensitivity of analysis. Semi-conductor nanocrystals or quantum dots (QDs) demonstrate several unique properties that make them suitable probes for biomolecular recognition. These QDs present narrow size-tunable emission spectra and a broad excitation spectrum; in addition, they offer higher photostability and brightness than conventional organic dyes. Our aim was to design a new diagnostic probe based on fluorescent nanobeads containing QDs, envi-sioned as a tool for fast and single-molecule detection. An even brighter fluorescence and easily detectable analytical signals could indeed be achieved by aggregating several thousand of QDs together, as compared to single QDs. Coating QD clusters with small surfactants or a polymer layer didn’t provide morphological control or a suitable surface chemistry for bioconjugation. The strategy that we developed consists in self-assembling QDs into monodisperse nanobeads of a few hundreds of nanometers in diameter, on top of which a silica shell was grown by a Stöber-inspired process. This allowed us to protect their colloidal and photo-stability. A new type of multidentate polymer-silane hybrid was subsequently grafted onto the silica shell, presenting a zwitterionic chain for water solubility and antifouling, as well as reactive functions for conjugation with biomolecules. We succeeded in reacting streptavidin-conjugated nanobeads with commercial biotinylated beads. Preliminary results have also shown that we can integrate the nanobeads into a microfluidic system for an efficient single-particle counting.
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Molecular Diagnostics Using Volume-Amplified Magnetic Nanobeads : Towards the Development of a Novel Biosensor SystemStrömberg, Mattias January 2009 (has links)
Micro- or nanometer sized magnetic particles (beads) currently have a vast range of life science applications in, for example, bioseparation techniques, cancer therapy, development of contrast agents and biosensing techniques. In the latter field, magnetic beads offer several unique advantages, including minimal background signals, physical and chemical stability and low manufacturing costs. Because of these properties, magnetic biosensing techniques are potential candidates for low-cost, easy-to-use molecular diagnostic devices. This doctoral thesis focuses mainly on the proof of principle and further development of a new magnetic biosensor platform for detection of DNA targets, a potential candidate for a new generation of low-cost, easy-to-use diagnostic devices: the Volume-Amplified Magnetic Nanobead Detection Assay (VAM-NDA). The VAM-NDA principle combines target recognition by padlock probe ligation followed by rolling circle amplification (RCA) of the reacted probes with changes in Brownian relaxation behaviour of magnetic nanobeads (typically ~100 nm in diameter) induced by a change in hydrodynamic bead volume. More specifically, the RCA products (coils, typically ~1 μm in diameter) are detected magnetically by adding magnetic beads tagged with detection probes complementary to part of the repeating RCA-coil sequence. Thus, depending on the target concentration, a certain quantity of beads binds to the coils by base-pair hybridisation (bead immobilisation), resulting in a dramatic bead volume increase, which is then detected by measuring the complex magnetisation spectrum. Use of a commercial SQUID magnetometer for measuring complex magnetisation resulted in a detection limit in the low pM range for DNA targets with excellent quantification accuracy. Simultaneous multiplexing was also evaluated. The stability and aging of typical commercial ferrofluids (suspensions of magnetic beads) were investigated by measuring the complex magnetisation of and interbead interactions in oligonucleotide-functionalised ferrofluids. In summary, the bead surface characteristics were found to have a strong impact on the measured dynamic magnetic properties.
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Novel diagnostic microarray assay formats towards comprehensive on-site analysisGantelius, Jesper January 2009 (has links)
Advances in molecular methods for analyzing DNA, RNA and proteins in humans as well as in other animals, plants, fungi, bacteria or viruses have greatly increased the resolution with which we can study life’s complexity and dynamics on earth. While genomic, transcriptomic and proteomic laboratory tools for molecular diagnosis of disease are rapidly becoming more comprehensive, the access to such advanced yet often expensive and centralized procedures is limited. There is a great need for rapid and comprehensive diagnostic methods in low-resource settings or contexts where a person can not or will not go to a hospital or medical laboratory, yet where a clinical analysis is urgent. In this thesis, results from development and characterization of novel technologies for DNA and protein microarray analysis are presented. Emphasis is on methods that could provide rapid, cost-effective and portable analysis with convenient readout and retained diagnostic accuracy. The first study presents a magnetic bead-based approach for DNA microarray analysis for a rapid visual detection of single nucleotide polymorphisms. In the second work, magnetic beads were used as detection reagents for rapid differential detection of presence of pestiviral family members using a DNA oligonucleotide microarray with read-out by means of a tabletop scanner or a digital camera. In paper three, autoimmune responses from human sera were detected on a protein autoantigen microarray, again by means of magnetic bead analysis. Here, special emphasis was made in comprehensively comparing the performance of the magnetic bead detection to common fluorescence-based detection. In the fourth study, an immunochromatographic lateral flow protein microarray assay is presented for application in the classification of contagious pleuropneumonia from bovine serum samples. The analysis could be performed within 10 minutes using a table top scanner, and the performance of the assay was shown to be comparable to that of a cocktail ELISA. In the fifth paper, the lateral flow microarray framework is investigated in further detail by means of experiments and numerical simulation. It was found that downstream effects play an important role, and the results further suggest that the downstream binding profiles may find use in simple affinity evaluation. / QC 20100713
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The fabrication process of microfluidic devices integrating microcoils for trapping magnetic nano particles for biological applications / Procédé de fabrication de dispositifs microfluidiques intégrant des microbobines – Piégeage de nanoparticules magnétiques pour des applications en biologieCao, Hong Ha 21 July 2015 (has links)
Le but de cette étude est de concevoir, fabriquer et caractériser une puce microfluidique afin de mettre en oeuve la capture de nanoparticules magnétiques fonctionnalisées en vue de la reconnaissance d’anticorps spécifiques (couplage d’une très grande spécificité et sensibilité). Après avoir modélisé et simulé les performances de la microbobine intégrée dans le canal de la puce microfluidique en prenant soin de limiter la température du fluide à 37°C, la capture devant être effective, le microsystème est fabriqué en salle blanche en utilisant des procédés de fabrication collective. La fabrication du microdispositif en PDMS a aussi donné lieu à l’optimisation de procédés de modification de surface afin d’assurer la ré-utilisation du microdispositif (packaging réversible) et la limitation de l’adsorption non spécifique. L’immobilisation des anticorps su les billes (300 nm) a été menée à l’intérieur du canal en utilisant un protocole de type ELISA éprouvé. Le procédé a montré qu’il était également efficient pour cet environnement puisque nous avons pu mettre ne évidence la capture de nanoparticules / In this study, a concept of microfluidic chip with embedded planar coils is designed and fabricated for the aim of trapping effectively functionalized magnetic nanobeads and immobilizing antibody (IgG type). The planar coils as a heart of microfluidic chip is designed with criterion parameters which are optimized from simulation parameters of the maximum magnetic field, low power consumption and high power efficiency by FE method. The characterization of microcoils such as effectively nanobeads (300 nm) at low temperature (<37oC) is performed and confirmed. The channel network in PDMS material is designed for matching with entire process (including mixing and trapping beads) in microfluidic chip. A process of PDMS’s surface modification is also carried out in the assemble step of chip in order to limit the non-specific adsorption of many bio substances on PDMS surface. The microfluidic chip assemble is performed by using some developed techniques of reversible packaging PDMS microfluidic chip (such as stamping technique, using non-adhesive layer, oxygen plasma combining with solvent treatment). These packaging methods are important to reused microchip (specially the bottom substrate) in many times. The immobilization of antibody IgG-type is performed inside microfluidic chip following the standard protocol of bead-based ELISA in micro test tube. The result showed that IgG antibodies are well grafted on the surface of carboxyl-beads (comparing to result of standard protocol); these grafted antibodies are confirmed by coupling them with labeled second antibody (Fab-FITC conjugation).
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