Your search keyword '"Ünlü M"' showing total 12 results

1. Beating the reaction limits of biosensor sensitivity with dynamic tracking of single binding events.

Author

Sevenler D, Trueb J, and Ünlü MS

Subjects

Interferometry, Biosensing Techniques, DNA analysis, Gold chemistry, Metal Nanoparticles chemistry, Nanotubes chemistry

Abstract

The clinical need for ultrasensitive molecular analysis has motivated the development of several endpoint-assay technologies capable of single-molecule readout. These endpoint assays are now primarily limited by the affinity and specificity of the molecular-recognition agents for the analyte of interest. In contrast, a kinetic assay with single-molecule readout could distinguish between low-abundance, high-affinity (specific analyte) and high-abundance, low-affinity (nonspecific background) binding by measuring the duration of individual binding events at equilibrium. Here, we describe such a kinetic assay, in which individual binding events are detected and monitored during sample incubation. This method uses plasmonic gold nanorods and interferometric reflectance imaging to detect thousands of individual binding events across a multiplex solid-phase sensor with a large area approaching that of leading bead-based endpoint-assay technologies. A dynamic tracking procedure is used to measure the duration of each event. From this, the total rates of binding and debinding as well as the distribution of binding-event durations are determined. We observe a limit of detection of 19 fM for a proof-of-concept synthetic DNA analyte in a 12-plex assay format., Competing Interests: The authors declare no conflict of interest.

Published

2019

2. Label-Free and High-Throughput Detection of Biomolecular Interactions Using a Flatbed Scanner Biosensor.

Author

Aygun U, Avci O, Seymour E, Urey H, Ünlü MS, and Ozkumur AY

Subjects

Biosensing Techniques methods, DNA chemistry, DNA metabolism, Fluorescence, High-Throughput Screening Assays methods, Humans, Interferometry, Light, Microarray Analysis methods, Nucleic Acid Hybridization, Biosensing Techniques instrumentation, DNA analysis, High-Throughput Screening Assays instrumentation, Microarray Analysis instrumentation, Optical Imaging methods

Abstract

Fluorescence based microarray detection systems provide sensitive measurements; however, variation of probe immobilization and poor repeatability negatively affect the final readout, and thus quantification capability of these systems. Here, we demonstrate a label-free and high-throughput optical biosensor that can be utilized for calibration of fluorescence microarrays. The sensor employs a commercial flatbed scanner, and we demonstrate transformation of this low cost (∼100 USD) system into an Interferometric Reflectance Imaging Sensor through hardware and software modifications. Using this sensor, we report detection of DNA hybridization and DNA directed antibody immobilization on label-free microarrays with a noise floor of ∼30 pg/mm 2 , and a scan speed of 5 s (50 s for 10 frames averaged) for a 2 mm × 2 mm area. This novel system may be used as a standalone label-free sensor especially in low-resource settings, as well as for quality control and calibration of microarrays in existing fluorescence-based DNA and protein detection platforms.

Published

2017

3. DNA-Directed Antibody Immobilization for Robust Protein Microarrays: Application to Single Particle Detection 'DNA-Directed Antibody Immobilization.

Author

Ünlü NL, Kanik FE, Seymour E, Connor JH, and Ünlü MS

Subjects

Biosensing Techniques instrumentation, DNA Probes, Image Processing, Computer-Assisted methods, Immunoconjugates, Microfluidics instrumentation, Microscopy methods, Molecular Imaging instrumentation, Protein Array Analysis instrumentation, Statistics as Topic methods, Viruses immunology, Antibodies, Immobilized, Biosensing Techniques methods, DNA, Molecular Imaging methods, Protein Array Analysis methods

Abstract

Protein microarrays are emerging tools which have become very powerful in multiplexed detection technologies. A variety of proteins can be immobilized on a sensor chip allowing for multiplexed diagnostics. Therefore, various types of analyte in a small volume of sample can be detected simultaneously. Protein immobilization is a crucial step for creating a robust and sensitive protein microarray-based detection system. In order to achieve a successful protein immobilization and preserve the activity of the proteins after immobilization, DNA-directed immobilization is a promising technique. Here, we present the design and the use of DNA-directed immobilized (DDI) antibodies in fabrication of robust protein microarrays. We focus on application of protein microarrays for capturing and detecting nanoparticles such as intact viruses. Experimental results on Single-particle interferometric reflectance imaging sensor (SP-IRIS) are used to validate the advantages of the DDI method.

Published

2017

4. Quantitative characterization of conformational-specific protein-DNA binding using a dual-spectral interferometric imaging biosensor.

Author

Zhang X, Daaboul GG, Spuhler PS, Dröge P, and Ünlü MS

Subjects

Binding Sites, DNA-Binding Proteins, Equipment Design, Escherichia coli metabolism, Fluorescence, Fluorescent Dyes chemistry, Humans, Hydrogen chemistry, Immobilized Nucleic Acids, Light, Magnetic Resonance Spectroscopy, Microscopy, Fluorescence, Nucleic Acid Conformation, Protein Array Analysis instrumentation, Spectrometry, Fluorescence, Surface Properties, Biosensing Techniques methods, DNA chemistry, Interferometry methods, Oligonucleotide Array Sequence Analysis methods, Proteins chemistry

Abstract

DNA-binding proteins play crucial roles in the maintenance and functions of the genome and yet, their specific binding mechanisms are not fully understood. Recently, it was discovered that DNA-binding proteins recognize specific binding sites to carry out their functions through an indirect readout mechanism by recognizing and capturing DNA conformational flexibility and deformation. High-throughput DNA microarray-based methods that provide large-scale protein-DNA binding information have shown effective and comprehensive analysis of protein-DNA binding affinities, but do not provide information of DNA conformational changes in specific protein-DNA complexes. Building on the high-throughput capability of DNA microarrays, we demonstrate a quantitative approach that simultaneously measures the amount of protein binding to DNA and nanometer-scale DNA conformational change induced by protein binding in a microarray format. Both measurements rely on spectral interferometry on a layered substrate using a single optical instrument in two distinct modalities. In the first modality, we quantitate the amount of binding of protein to surface-immobilized DNA in each DNA spot using a label-free spectral reflectivity technique that accurately measures the surface densities of protein and DNA accumulated on the substrate. In the second modality, for each DNA spot, we simultaneously measure DNA conformational change using a fluorescence vertical sectioning technique that determines average axial height of fluorophores tagged to specific nucleotides of the surface-immobilized DNA. The approach presented in this paper, when combined with current high-throughput DNA microarray-based technologies, has the potential to serve as a rapid and simple method for quantitative and large-scale characterization of conformational specific protein-DNA interactions.

Published

2016

5. DNA-Directed Antibody Immobilization for Enhanced Detection of Single Viral Pathogens.

Author

Seymour E, Daaboul GG, Zhang X, Scherr SM, Ünlü NL, Connor JH, and Ünlü MS

Subjects

Microscopy, Fluorescence instrumentation, Vesiculovirus pathogenicity, Antibodies, Immobilized chemistry, Biosensing Techniques instrumentation, DNA chemistry, DNA Probes chemistry, Vesiculovirus isolation & purification

Abstract

Here, we describe the use of DNA-conjugated antibodies for rapid and sensitive detection of whole viruses using a single-particle interferometric reflectance imaging sensor (SP-IRIS), a simple, label-free biosensor capable of imaging individual nanoparticles. First, we characterize the elevation of the antibodies conjugated to a DNA sequence on a three-dimensional (3-D) polymeric surface using a fluorescence axial localization technique, spectral self-interference fluorescence microscopy (SSFM). Our results indicate that using DNA linkers results in significant elevation of the antibodies on the 3-D polymeric surface. We subsequently show the specific detection of pseudotyped vesicular stomatitis virus (VSV) as a model virus on SP-IRIS platform. We demonstrate that DNA-conjugated antibodies improve the capture efficiency by achieving the maximal virus capture for an antibody density as low as 0.72 ng/mm(2), whereas for unmodified antibody, the optimal virus capture requires six times greater antibody density on the sensor surface. We also show that using DNA conjugated anti-EBOV GP (Ebola virus glycoprotein) improves the sensitivity of EBOV-GP carrying VSV detection compared to directly immobilized antibodies. Furthermore, utilizing a DNA surface for conversion to an antibody array offers an easier manufacturing process by replacing the antibody printing step with DNA printing. The DNA-directed immobilization technique also has the added advantages of programmable sensor surface generation based on the need and resistance to high temperatures required for microfluidic device fabrication. These capabilities improve the existing SP-IRIS technology, resulting in a more robust and versatile platform, ideal for point-of-care diagnostics applications.

Published

2015

6. Copolymer-Coated Gold Nanoparticles: Enhanced Stability and Customizable Functionalization for Biological Assays.

Author

Brambilla, Dario, Panico, Federica, Zarini, Lorenzo, Mussida, Alessandro, Ferretti, Anna M., Aslan, Mete, Ünlü, M. Selim, and Chiari, Marcella

Subjects

CHEMICAL reactions, BIOLOGICAL assay, GOLD nanoparticles, NANOPARTICLES, TRANSMISSION electron microscopy

Abstract

Gold nanoparticles (AuNPs) play a vital role in biotechnology, medicine, and diagnostics due to their unique optical properties. Their conjugation with antibodies, antigens, proteins, or nucleic acids enables precise targeting and enhances biosensing capabilities. Functionalized AuNPs, however, may experience reduced stability, leading to aggregation or loss of functionality, especially in complex biological environments. Additionally, they can show non-specific binding to unintended targets, impairing assay specificity. Within this work, citrate-stabilized and silica-coated AuNPs (GNPs and SiGNPs, respectively) have been coated using N,N-dimethylacrylamide-based copolymers to increase their stability and enable their functionalization with biomolecules. AuNP stability after modification has been assessed by a combination of techniques including spectrophotometric characterization, nanoparticle tracking analysis, transmission electron microscopy and functional microarray tests. Two different copolymers were identified to provide a stable coating of AuNPs while enabling further modification through click chemistry reactions, due to the presence of azide groups in the polymers. Following this experimental design, AuNPs decorated with ssDNA and streptavidin were synthesized and successfully used in a biological assay. In conclusion, a functionalization scheme for AuNPs has been developed that offers ease of modification, often requiring single steps and short incubation time. The obtained functionalized AuNPs offer considerable flexibility, as the functionalization protocol can be personalized to match requirements of multiple assays. [ABSTRACT FROM AUTHOR]

Published

2024

7. Platform for in Situ Real-Time Measurement of Protein-Induced Conformational Changes of DNA

Author

Spuhler, Philipp S., Knežević, Jelena, Yalçin, Ayça, Bao, Qiuye, Pringsheim, Erika, Dröge, Peter, Rant, Ulrich, Ünlü, M. Selim, and Cantor, Charles R.

Published

2010

8. DNA Conformation on Surfaces Measured by Fluorescence Self-Interference

Author

Moiseev, Lev, Ünlü, M. Selim, Swan, Anna K., Goldberg, Bennett B., and Cantor, Charles R.

Published

2006

9. Nanoscale characterization of DNA conformation using dual-color fluorescence axial localization and label-free biosensing.

Author

Zhang, Xirui, Daaboul, George G., Spuhler, Philipp S., Freedman, David S., Yurt, Abdulkadir, Ahn, Sunmin, Avci, Oguzhan, and Ünlü, M. Selim

Subjects

DNA, NANOSENSORS, FLUORESCENCE spectroscopy, FLUOROPHORES, BIOMOLECULES, FLUORESCENCE

Abstract

Quantitative determination of the density and conformation of DNA molecules tethered to the surface can help optimize and understand DNA nanosensors and nanodevices, which use conformational or motional changes of surface-immobilized DNA for detection or actuation. We present an interferometric sensing platform that combines (i) dual-color fluorescence spectroscopy for precise axial co-localization of two fluorophores attached at different nucleotides of surface-immobilized DNA molecules and (ii) independent label-free quantification of biomolecule surface density at the same site. Using this platform, we examined the conformation of DNA molecules immobilized on a three-dimensional polymeric surface and demonstrated simultaneous detection of DNA conformational change and binding in real-time. These results demonstrate that independent quantification of both surface density and molecular nanoscale conformation constitutes a versatile approach for nanoscale solid-biochemical interface investigations and molecular binding assays. [ABSTRACT FROM AUTHOR]

Published

2014

10. Precisely Controlled Smart Polymer Scaffold for Nanoscale Manipulation of Biomolecules.

Author

Spuhler, Philipp S., Sola, Laura, Zhang, Xirui, Monroe, Margo R., Greenspun, Joseph T., Chiari, Marcella, and Ünlü, M. Selim

Subjects

*BIOMOLECULES, *DNA, *POLYMERS, *SURFACE coatings, *ORIENTATION (Chemistry), *MOLECULAR conformation, *MICROFABRICATION

Abstract

We demonstrate the application of a novel smart surface to modulate the orientation of immobilized double stranded DNA (dsDNA) and the conformation of a polymer scaffold through variation in buffer pH and ionic strength. An amphoteric poly(dimethylacrylamide) based coating containing weak acrylamido acids and bases, which are copolymerized together with the neutral monomer, is covalently bound to the surface. The coating can be made to contain any desired amount of buffering and titrant ionogenic monomers, allowing control of the surface charge when the surface is bathed in a given buffer pH. Spectral self-interference fluorescence microscopy (SSFM) is utilized to precisely quantify both the DNA orientation and the polymer conformation with subnanometer resolution. It is possible to utilize the polymer scaffold to functionalize a variety of common materials used in microfabrication, making it a general purpose building block for the next generation of nanomachines and biosensors. [ABSTRACT FROM AUTHOR]

Published

2012

11. Label-free microarray imaging for direct detection of DNA hybridization and single-nucleotide mismatches

Author

Özkumur, Emre, Ahn, Sunmin, Yalçın, Ayça, Lopez, Carlos A., Çevik, Elif, Irani, Rostem J., DeLisi, Charles, Chiari, Marcella, and Selim Ünlü, M.

Subjects

*DNA microarrays, *NUCLEIC acid hybridization, *DNA, *NUCLEOTIDES, *GENETIC polymorphisms, *BIOSENSORS, *OPTICAL interferometers

Abstract

Abstract: A novel method is proposed for direct detection of DNA hybridization on microarrays. Optical interferometry is used for label-free sensing of biomolecular accumulation on glass surfaces, enabling dynamic detection of interactions. Capabilities of the presented method are demonstrated by high-throughput sensing of solid-phase hybridization of oligonucleotides. Hybridization of surface immobilized probes with 20 base pair-long target oligonucleotides was detected by comparing the label-free microarray images taken before and after hybridization. Through dynamic data acquisition during denaturation by washing the sample with low ionic concentration buffer, melting of duplexes with a single-nucleotide mismatch was distinguished from perfectly matching duplexes with high confidence interval (>97%). The presented technique is simple, robust, and accurate, and eliminates the need of using labels or secondary reagents to monitor the oligonucleotide hybridization. [Copyright &y& Elsevier]

Published

2010

12. Quantification of DNA and protein adsorption by optical phase shift

Author

Özkumur, Emre, Yalçın, Ayça, Cretich, Marina, Lopez, Carlos A., Bergstein, David A., Goldberg, Bennett B., Chiari, Marcella, and Ünlü, M. Selim

Subjects

*ADSORPTION (Chemistry), *PROTEINS, *DNA, *BIOSENSORS, *BIOMOLECULES, *DNA microarrays, *MOLECULE-molecule collisions, *FLUORESCENCE

Abstract

Abstract: A primary advantage of label-free detection methods over fluorescent measurements is its quantitative detection capability, since an absolute measure of adsorbed material facilitates kinetic characterization of biomolecular interactions. Interferometric techniques relate the optical phase to biomolecular layer density on the surface, but the conversion factor has not previously been accurately determined. We present a calibration method for phase shift measurements and apply it to surface-bound bovine serum albumin, immunoglobulin G, and single-stranded DNA. Biomolecules with known concentrations dissolved in salt-free water were spotted with precise volumes on the array surface and upon evaporation of the water, left a readily calculated mass. Using our label-free technique, the calculated mass of the biolayer was compared with the measured thickness, and we observed a linear dependence over 4 orders of magnitude. We determined that the widely accepted conversion of 1nm of thickness corresponds to ∼1ng/mm2 surface density held reasonably well for these substances and through our experiments can now be further specified for different types of biomolecules. Through accurate calibration of the dependence of thickness on surface density, we have established a relation allowing precise determination of the absolute number of molecules for single-stranded DNA and two different proteins. [Copyright &y& Elsevier]

Published

2009