Magnetic Bead Based Immunoassay for Autonomous Detection of Toxins

Kwon, Youngeun; Hara, Christine A.; Knize, Mark G.; Hwang, Mona; Venkateswaran, K.; Wheeler, Elizabeth K.; Bell, P. M.; Renzi, Ronald F.; Fruetel, Julie A.; Bailey, Christopher G.

doi:10.1021/ac8010044

Cited by 37 publications

(27 citation statements)

References 22 publications

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“…Alternatively, an automated fluidic system consisting of a pump, multichannel selection valve, renewable surface flow cell and on cell detector has been developed to perform sandwich immunoassays (Figure 3) [73,74,75,76]. A given sample solution is applied on beads coated with capture antibody, followed by application of detection antibody and readout by built-in detector, all in an autonomous fashion.…”

Section: Elisamentioning

confidence: 99%

Sensing the Deadliest Toxin: Technologies for Botulinum Neurotoxin Detection

Čapek

Dickerson

2010

Toxins

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Sensitive and rapid detection of botulinum neurotoxins (BoNTs), the most poisonous substances known to date, is essential for studies of medical applications of BoNTs and detection of poisoned food, as well as for response to potential bioterrorist threats. Currently, the most common method of BoNT detection is the mouse bioassay. While this assay is sensitive, it is slow, quite expensive, has limited throughput and requires sacrificing animals. Herein, we discuss and compare recently developed alternative in vitro detection methods and assess their ability to supplement or replace the mouse bioassay in the analysis of complex matrix samples.

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Section: Elisamentioning

confidence: 99%

Sensing the Deadliest Toxin: Technologies for Botulinum Neurotoxin Detection

Čapek

Dickerson

2010

Toxins

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“…Furthermore, MMPs can be easily collected with a magnet, allowing mercury enrichment and sensor regeneration to be conveniently carried out. MMPs have been used 2 for the detection of DNA, [37,38] small molecules, [39] toxins, [40] proteins, [41][42][43] and cells. [44] For most of the assays, covalent fluorophore labeling was required for fluorescence generation.…”

Section: Introductionmentioning

confidence: 99%

Immobilization of DNA on Magnetic Microparticles for Mercury Enrichment and Detection with Flow Cytometry

Huang

Liu

2011

Chemistry A European J

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Mercury detection in water has attracted a lot of research interest due to its highly toxic nature and adverse environmental impact. In particular, the recent discovery of specific binding of Hg (II) to thyminerich DNA resulting in T-Hg (II) -T base pairs has led to the development of a number of sensors with different signaling mechanisms. However, majority of such sensors were nonimmobilized. Immobilization, on the other hand, allows active mercury adsorption, signal amplification, and sensor regeneration. In this work, we immobilized a thymine-rich DNA on a magnetic microparticle surface via biotin-streptavidin interactions. In the presence of Hg (II) , the DNA changes from a random coil structure into a hairpin, upon which SYBR Green I binds to emit green fluorescence. Detection was carried out using flow cytometry where fluorescence intensity increased ~9-fold in the presence of mercury and the binding of mercury reached equilibrium in less than 2 min. The sensor showed a unique samplevolume dependent fluorescence signal change where a higher fluorescence was obtained with a larger sample volume, suggesting that the particles can actively adsorb Hg (II) . Detection limits of 5 nM (1 ppb) and 14 nM (2.8 ppb) were achieved in pure buffer and in mercury spiked Lake Ontario water samples, respectively.

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“…Examples in literature report on a high-throughput automated immunoassay for 3-phenoxybenzoic acid [204] or toxins [205]. Such systems are interesting for unattended measurements or whenever analyses are carried out by untrained operators.…”

Section: Fluorescence-based Immunoassaysmentioning

confidence: 99%

Luminescent magnetic particles: structures, syntheses, multimodal imaging, and analytical applications

Mistlberger

Klimant

2010

Bioanal Rev

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Luminescent magnetic particles (LuMaPs) are attractive tools for life science applications such as multimodal imaging, analyte monitoring, nanotherapeutics, and combinations thereof. LuMaPs consist of at least one magnetic and one luminescent component which often are incorporated in a (polymeric) matrix. A large variety of materials do exist for the components that make up LuMaPs. However, a smart selection and combination is required for achieving useful tools. While the magnetic component mainly influences the response to a magnetic field, the luminophore can act as label, sensor, or therapeutic agent. The matrix fulfills tasks such as stabilizing the luminophore and magnet, carrying useful functional groups on its surface, or hosting smart drug delivery systems. Surface modifications with targeting ligands can further improve the applicability of LuMaPs, for example in biomedicine. This review provides an overview on LuMaPs with respect to the materials used and to its structures. Routes toward LuMaPs are outlined, and potential applications are discussed.

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Magnetic Bead Based Immunoassay for Autonomous Detection of Toxins

Cited by 37 publications

References 22 publications

Sensing the Deadliest Toxin: Technologies for Botulinum Neurotoxin Detection

Sensing the Deadliest Toxin: Technologies for Botulinum Neurotoxin Detection

Immobilization of DNA on Magnetic Microparticles for Mercury Enrichment and Detection with Flow Cytometry

Luminescent magnetic particles: structures, syntheses, multimodal imaging, and analytical applications

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