9 results on '"John P. Nolan"'
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2. Optimization of SERS Tag Intensity, Binding Footprint, and Emittance
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Danilo Condello, Erika Duggan, and John P. Nolan
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Silver ,Receptor, ErbB-2 ,Dispersity ,Biomedical Engineering ,Metal Nanoparticles ,Pharmaceutical Science ,Nanoparticle ,Antineoplastic Agents ,Breast Neoplasms ,Bioengineering ,Nanotechnology ,Antibodies, Monoclonal, Humanized ,Spectrum Analysis, Raman ,Article ,Footprint (electronics) ,symbols.namesake ,Tumor Cells, Cultured ,Humans ,Thermal emittance ,Surface plasmon resonance ,Coloring Agents ,Fluorescent Dyes ,Pharmacology ,Nanotubes ,Chemistry ,Organic Chemistry ,Serum Albumin, Bovine ,Surface Plasmon Resonance ,Trastuzumab ,Avidin ,Flow Cytometry ,Microspheres ,symbols ,Female ,Nanorod ,Gold ,Intensity (heat transfer) ,Raman scattering ,Biotechnology - Abstract
Nanoparticle surface enhanced Raman scattering (SERS) tags have attracted interest as labels for use in a variety of applications, including biomolecular assays. An obstacle to progress in this area is a lack of standardized approaches to compare the brightness of different SERS tags within and between laboratories. Here we present an approach based on binding of SERS tags to beads with known binding capacities that allows evaluation of the average intensity, the relative binding footprint of particles in a SERS tag preparation, and the size-normalized intensity or emittance. We tested this on four different SERS tag compositions and show that aggregated gold nanorods produce SERS tags that are 2-4 times brighter than relatively more monodisperse nanorods, but that the aggregated nanorods are also correspondingly larger, which may negate the intensity if steric hindrance limits the number of tags bound to a target. By contrast, SERS tags prepared from smaller gold nanorods coated with a silver shell produce SERS tags that are 2-3 times brighter, on a size-normalized basis, than the Au nanorod-based tags, resulting in labels with improved performance in SERS-based image and flow cytometry assays. SERS tags based on red-resonant Ag plates showed similarly bright signals and small footprint. This approach to evaluating SERS tag brightness is general, uses readily available reagents and instruments, and should be suitable for interlab comparisons of SERS tag brightness.
- Published
- 2014
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3. High Throughput Single Nanoparticle Spectroscopy
- Author
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John P. Nolan, Dakota A. Watson, and David S. Sebba
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Materials science ,General Engineering ,General Physics and Astronomy ,Nanoparticle ,Nanotechnology ,Nanoengineering ,Spectrum Analysis, Raman ,Article ,Characterization (materials science) ,symbols.namesake ,symbols ,Nanoparticles ,General Materials Science ,Rayleigh scattering ,Spectroscopy ,Throughput (business) ,Plasmon ,Raman scattering - Abstract
Progress in the development and application of nanoengineered systems is limited by the availability of quantitative measurement techniques. For the engineering of nanoparticle (NP)-based systems, single NP characterization is essential, but existing methods are slow and low throughput. We demonstrate a flow spectroscopy technique capable of analyzing hundreds of nanoparticles per second and use this technique for the high throughput analysis of nanoparticle surface-enhanced resonant Raman scattering (SERRS) tags. By measuring Rayleigh and Raman scattering from thousands of individual tags, tag preparations can be characterized based on their brightness and uniformity. The rapid analysis of individual nanoparticles using high spectral resolution flow spectroscopy will be useful in many areas of nanoengineering.
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- 2009
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4. Probing the Kinetics of SYTOX Orange Stain Binding to Double-Stranded DNA with Implications for DNA Analysis
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Robert C. Habbersett, James H. Jett, Xiaomei Yan, Thomas M. Yoshida, John P. Nolan, and Babetta L. Marrone
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Binding Sites ,Time Factors ,Chromatography ,Staining and Labeling ,Chemistry ,Kinetics ,Fluorescence spectrometry ,DNA ,Flow Cytometry ,Sensitivity and Specificity ,Stain ,Fluorescence ,Receptor–ligand kinetics ,Analytical Chemistry ,Staining ,Structure-Activity Relationship ,chemistry.chemical_compound ,Spectrometry, Fluorescence ,Organic Chemicals ,Particle Size ,Binding site - Abstract
Rapid binding kinetics of SYTOX Orange stain with double-stranded DNA (dsDNA) was revealed on the DNA fragment sizing flow cytometer. We demonstrated for the first time that the dye molecules could be adsorbed onto the capillary surface and native DNA fragments can be dynamically stained while passing through the capillary. High-quality burst size distribution histograms were obtained for DNA samples analyzed immediately after staining, dilution, or mixing. These observations indicated that rapid interactions exist between SYTOX Orange dye molecules and dsDNA. A stopped-flow fluorescence apparatus was set up to capture the fast association traces of intercalating dyes binding to dsDNA. Kinetic equations were derived to fit the association curves for determination of association rates and to model the dynamic staining, dilution, and mixing processes of DNA samples stained with intercalating dyes. The measured association rates for both SYTOX Orange and PicoGreen stains intercalating into dsDNA were on the order of 10(8) M-1 s-1, suggesting a diffusion-controlled process. Simulations indicate that reequilibration can be reached in seconds upon staining, dilution, or mixing. Insight into the kinetics of DNA binding dyes will help implement efficient sample-handling practices in DNA analysis, including DNA fragment sizing flow cytometry.
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- 2005
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5. Analysis of Cholera Toxin−Ganglioside Interactions by Flow Cytometry
- Author
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Byron Goldstein, Sabine Lauer, John P. Nolan, and Rhiannon L. Nolan
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Cholera Toxin ,Phospholipid ,Receptors, Cell Surface ,G(M1) Ganglioside ,In Vitro Techniques ,medicine.disease_cause ,Models, Biological ,Biochemistry ,chemistry.chemical_compound ,Gangliosides ,medicine ,Animals ,Avidity ,Binding site ,Receptor ,Fluorescent Dyes ,Binding Sites ,Ganglioside ,Cell Membrane ,Cholera toxin ,Flow Cytometry ,Binding constant ,Molecular biology ,Kinetics ,Protein Subunits ,A-site ,chemistry ,Liposomes ,Biophysics ,Fluorescein-5-isothiocyanate - Abstract
Cholera toxin entry into mammalian cells is mediated by binding of the pentameric B subunit (CTB) to ganglioside GM(1) in the cell membrane. We used flow cytometry to quantitatively measure in real time the interactions of fluorescently labeled pentameric cholera toxin B-subunit (FITC-CTB) with its ganglioside receptor on microsphere-supported phospholipid membranes. A model that describes the multiple steps of this mode of recognition was developed to guide our flow cytometric experiments and extract relevant equilibrium and kinetic rate constants. In contrast to previous studies, our approach takes into account receptor cross-linking, an important feature for multivalent interactions. From equilibrium measurements, we determined an equilibrium binding constant for a single subunit of FITC-CTB binding monovalently to GM(1) presented in bilayers of approximately 8 x 10(7) M(-1) while that for binding to soluble GM(1)-pentasaccharide was found to be approximately 4 x 10(6) M(-1). From kinetic measurements, we determined the rate constant for dissociation of a single site of FITC-CTB from microsphere-supported bilayers to be (3.21 +/- 0.03) x 10(-3) s(-1), and the rate of association of a site on FITC-CTB in solution to a GM(1) in the bilayer to be (2.8 +/- 0.4) x 10(4) M(-1) s(-1). These values yield a lower estimate for the equilibrium binding constant of approximately 1 x 10(7) M(-1). We determined the equilibrium surface cross-linking constant [(1.1 +/- 0.1) x 10(-12) cm(2)] and from this value and the value for the rate constant for dissociation derived a value of approximately 3.5 x 10(-15) cm(2) s(-1) for the forward rate constant for cross-linking. We also compared the interaction of the receptor binding B-subunit with that of the whole toxin (A- and B-subunits). Our results show that the whole toxin binds with approximately 100-fold higher avidity than the pentameric B-subunit alone which is most likely due to the additional interaction of the A(2)-subunit with the membrane surface. Interaction of cholera toxin B-subunit and whole cholera toxin with gangliosides other than GM(1) revealed specific binding only to GD1(b) and asialo-GM(1). These interactions, however, are marked by low avidity and require high receptor concentrations to be observed.
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- 2002
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6. Ligand Receptor Dynamics at Streptavidin-Coated Particle Surfaces: A Flow Cytometric and Spectrofluorimetric Study
- Author
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Larry A. Sklar, Gabriel P. Lopez, John P. Nolan, Greg M. Jones, Jan F. Keij, and Tione Buranda
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Streptavidin ,Quenching (fluorescence) ,Chromatography ,Chemistry ,Ligand ,Kinetics ,Surfaces, Coatings and Films ,chemistry.chemical_compound ,Biotin ,Materials Chemistry ,Biophysics ,Moiety ,Physical and Theoretical Chemistry ,Binding site ,Fluorescein - Abstract
We have the studied the binding of 5-((N-(5-(N-(6-(biotinoyl)amino)hexanoyl)amino)pentyl)thioureidyl)fluorescein (fluorescein biotin) to 6.2 μm diameter, streptavidin-coated polystyrene beads using a combination of fluorimetric and flow cytometric methods. We have determined the average number of binding sites per bead, the extent of fluorescein quenching upon binding to the bead, and the association and dissociation kinetics. We estimate the site number to be ≈1 million per bead. The binding of the fluorescein biotin ligand occurs in steps where the insertion of the biotin moiety into one receptor pocket is followed immediately by the capture of the fluorescein moiety by a neighboring binding pocket; fluorescence quenching is a consequence of this secondary binding. At high surface coverage, the dominant mechanism of quenching appears to be via the formation of nonfluorescent nearest-neighbor aggregates. At early times, the binding process is characterized by biphasic association and dissociation kinetic...
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- 1999
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7. Kinetic Analysis of Human Flap Endonuclease-1 by Flow Cytometry
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John P. Nolan, Min Soo Park, Binghui Shen, and Larry A. Sklar
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Exonuclease ,biology ,Chemistry ,Kinetics ,Flap structure-specific endonuclease 1 ,DNA replication ,Cleavage (embryo) ,Biochemistry ,law.invention ,Endonuclease ,chemistry.chemical_compound ,law ,biology.protein ,Recombinant DNA ,Biophysics ,DNA - Abstract
Human flap endonuclease-1 (FEN-1) is a structure-specific endonuclease and exonuclease which is essential for DNA replication and repair. We have cloned a human FEN-1 gene, overexpressed it in Escherichia coli, purified the recombinant protein to near homogeneity, and characterized its cleavage of a flap DNA structure using a novel analytical approach based on flow cytometry. With this approach, we were able to measure continuously the kinetics of DNA cleavage by FEN-1 and to separate experimentally the binding and catalysis functions of the enzyme. When the reaction was initiated by the addition of FEN-1, the cleavage kinetics were dependent on enzyme concentration and appeared to saturate at high concentrations. When enzyme and substrate were preincubated in the presence of EDTA and the reaction initiated by the addition of Mg2+, rapid kinetic flow cytometry measurements showed that cleavage is fast (t1/2 approximately 6 s, k = 0.10 s-1). Using the single-turnover kinetics as a measure of the amount of enzyme-substrate complex present, we estimated the Kd for the FEN-1-flap DNA substrate to be 7.5 nM in the absence of Mg2+ and the rate constant for dissociation of the enzyme-substrate complex to be 0.07 s-1. Computer fitting of the experimental data to a kinetic model confirms these estimates for the individual steps and suggests some interesting features of enzymology using a surface-bound substrate.
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- 1996
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8. Optical Biosensor Based on Fluorescence Resonance Energy Transfer: Ultrasensitive and Specific Detection of Protein Toxins
- Author
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John P. Nolan, Xuedong Song, and Basil I. Swanson
- Subjects
Colloid and Surface Chemistry ,Förster resonance energy transfer ,Specific detection ,Chemistry ,Analytical chemistry ,Nanotechnology ,General Chemistry ,Optical biosensor ,Biochemistry ,Catalysis - Published
- 1998
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9. Optical Signal Transduction Triggered by Protein−Ligand Binding: Detection of Toxins Using Multivalent Binding
- Author
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John P. Nolan, Xuedong Song, and Basil I. Swanson
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Colloid and Surface Chemistry ,Chemistry ,Biophysics ,General Chemistry ,Signal transduction ,Multivalent binding ,Biochemistry ,Catalysis ,Protein ligand - Published
- 1998
- Full Text
- View/download PDF
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