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9 results on '"Jung-Soo Lee"'

1. Detection of nucleotides in hydrated ssDNA via 2D h‐BN nanopore with ionic‐liquid/salt–water interface

Author

Min Jun Kim, Jinguo Wang, Yapa Mudiyanselage Nuwan Dhananjaya Yapa Bandara, Moon J. Kim, Qingxiao Wang, Jung Soo Lee, Xin Peng, Kevin Garcia, Juan Pablo Oviedo, and Longsheng Xia

Subjects
Materials science, Clinical Biochemistry, DNA, Single-Stranded, Ionic Liquids, 02 engineering and technology, Conductivity, 01 natural sciences, Biochemistry, Analytical Chemistry, Nucleobase, Nanopores, chemistry.chemical_compound, Electrical resistivity and conductivity, Hexafluorophosphate, Molecule, Aqueous solution, Nucleotides, 010401 analytical chemistry, Water, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Nanopore, chemistry, Chemical physics, Ionic liquid, 0210 nano-technology
Abstract

Accomplishing slow translocation speed with high sensitivity has been the most critical mission for solid-state nanopore (SSN) device to electrically detect nucleobases in ssDNA. In this study, a method to detect nucleobases of ssDNA using a 2D SSN is introduced by considerably reducing the translocation speed and effectively increasing its sensitivity. The ultra-thin titanium dioxide coated hexagonal boron nitride nanopore was fabricated, along with an ionic-liquid 1-butyl-3-methylimidazolium hexafluorophosphate/2.0 M KCl aqueous (cis/trans) interface, for increasing both the spatial and the temporal resolutions. As the ssDNA molecules entered the nanopore, a brief surge of electrical conductivity occurred, which was followed by multiple resistive pulses from nucleobases during the translocation of ssDNA and another brief current surge flagging the exit of the molecule. The continuous detection of nucleobases using a 2D SSN device is a novel achievement: the water molecules bound to ssDNA increased the molecular conductivity and amplified electrical signals during the translocation. Along with the experiment, computational simulations using COMSOL Multiphysics are presented to explain the pivotal role of water molecules bound to ssDNA to detect nucleobases using a 2D SSN.

Published
2021

2. Fabrication of hexagonal boron nitride based 2D nanopore sensor for the assessment of electro‐chemical responsiveness of human serum transferrin protein

Author

Jugal Saharia, Y. M. Nuwan D. Y. Bandara, Jung Soo Lee, Moon J. Kim, Qingxiao Wang, and Min Jun Kim

Subjects
Boron Compounds, Analyte, Void (astronomy), Materials science, Fabrication, Protein Conformation, Clinical Biochemistry, Analytical chemistry, 02 engineering and technology, Dielectric, 01 natural sciences, Biochemistry, Analytical Chemistry, Nanopores, Parasitic capacitance, Humans, Titanium, 010401 analytical chemistry, Transferrin, Conductance, Electrochemical Techniques, Equipment Design, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Nanopore, Thermodynamics, 0210 nano-technology, Voltage
Abstract

In this work, we present a step-by-step workflow for the fabrication of 2D hexagonal boron nitride (h-BN) nanopores which are then used to sense holo-human serum transferrin (hSTf) protein at pH ∼8 under applied voltages ranging from +100 mV to +800 mV. 2D nanopores are often used for DNA, however, there is a great void in the literature for single-molecule protein sensing and this, to the best of our knowledge, is the first time where h-BN-a material with large band-gap, low dielectric constant, reduced parasitic capacitance and minimal charge transfer induced noise-is used for protein profiling. The corresponding ΔG (change in pore conductance due to analyte translocation) profiles showed a bimodal Gaussian distribution where the lower and higher ΔG distributions were attributed to (pseudo-) folded and unfolded conformations respectively. With increasing voltage, the voltage induced unfolding increased (evident by decrease in ΔG) and plateaued after ∼400 mV of applied voltage. From the ΔG versus voltage profile corresponding to the pseudo-folded state, we calculated the molecular radius of hSTf, and was found to be ∼3.1 nm which is in close concordance with the literature reported value of ∼3.25 nm.

Published
2019

3. Stiffness measurement of nanosized liposomes using solid‐state nanopore sensor with automated recapturing platform

Author

Jung Soo Lee, Moon J. Kim, Qingxiao Wang, Buddini Iroshika Karawdeniya, Jugal Saharia, Y. M. Nuwan D. Y. Bandara, Gaurav Goyal, Armin Darvish, and Min Jun Kim

Subjects
Materials science, Clinical Biochemistry, Nanoparticle, 02 engineering and technology, 01 natural sciences, Biochemistry, Analytical Chemistry, Automation, Nanopores, chemistry.chemical_compound, Electricity, medicine, Nanotechnology, Liposome, business.industry, Vesicle, 010401 analytical chemistry, Stiffness, 021001 nanoscience & nanotechnology, Elasticity, Microspheres, 0104 chemical sciences, Nanopore, chemistry, Liposomes, Polystyrenes, Particle, Optoelectronics, Polystyrene, medicine.symptom, 0210 nano-technology, business, Voltage
Abstract

This paper describes a method to gauge the stiffness of nanosized liposomes – a nanoscale vesicle – using a custom-made recapture platform coupled to a solid-state nanopore sensor. The recapture platform electrically profiles a given liposome vesicle multiple times through automated reversal of the voltage polarity immediately following a translocation instance to re-translocate the same analyte through the nanopore – provides better statistical insight at the molecular level by analyzing the same particle multiple times compared to conventional nanopore platforms. The capture frequency depends on the applied voltage with lower voltages (i.e., 100 mV) permitting higher recapture instances than at higher voltages (>200 mV) since the probability of particles exiting the nanopore capture radius increases with voltage. The shape deformation was inferred by comparing the normalized relative current blockade ((Formula presented.) at the two voltage polarities to that of a rigid particle, i.e., polystyrene beads. We found that liposomes deform to adopt a prolate shape at higher voltages. This platform can be further applied to investigate the stiffness of other types of soft matters, e.g., virus, exosomes, endosomes, and accelerate the potential studies in pharmaceutics for increasing the drug packing and unpacking mechanism by controlling the stiffness of the drug vesicles.

Published
2019

5. Multiple consecutive recapture of rigid nanoparticles using a solid-state nanopore sensor

Author

Jung Soo Lee, Seungjin Nam, Min Jun Kim, Chi Won Ahn, Bin Peng, Moon J. Kim, and Ahmet C. Sabuncu

Subjects
Time Factors, Materials science, Surface Properties, Capacitive sensing, Clinical Biochemistry, Population, Solid-state, Nanoparticle, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Biochemistry, Article, Analytical Chemistry, Diffusion, Nanopores, Electromagnetic Fields, Measurement precision, Computer Simulation, Particle Size, education, Resistive touchscreen, education.field_of_study, Silicon Compounds, 021001 nanoscience & nanotechnology, Dynamic Light Scattering, 0104 chemical sciences, Nanopore, Nanoparticles, Polystyrenes, Particle, 0210 nano-technology, Biological system, Porosity
Abstract

Solid-state nanopore sensors have been used to measure the size of a nanoparticle by applying a resistive pulse sensing technique. Previously, the size distribution of the population pool could be investigated utilizing data from a single translocation, however, the accuracy of the distribution is limited due to the lack of repeated data. In this study, we characterized polystyrene nanobeads utilizing single particle recapture techniques, which provide a better statistical estimate of the size distribution than that of single sampling techniques. The pulses and translocation times of two different sized nanobeads (80 nm and 125 nm in diameter) were acquired repeatedly as nanobeads were recaptured multiple times using an automated system controlled by custom-built scripts. The drift-diffusion equation was solved to find good estimates for the configuration parameters of the recapture system. The results of the experiment indicated enhancement of measurement precision and accuracy as nanobeads were recaptured multiple times. Reciprocity of the recapture and capacitive effects in solid state nanopores are discussed. Our findings suggest that solid-state nanopores and an automated recapture system can also be applied to soft nanoparticles, such as liposomes, exosomes, or viruses, to analyze their mechanical properties in single-particle resolution. This article is protected by copyright. All rights reserved

Published
2017

7. Back Cover: Mechanical characterization of HIV-1 with a solid-state nanopore sensor

Author

Prashanta Dutta, Y. M. Nuwan D. Y. Bandara, Irwin Chaiken, Armin Darvish, Jungsuk Kim, Gaurav Goyal, Ramalingam Venkat Kalyana Sundaram, Bin Peng, Jung Soo Lee, Jugal Saharia, Min Jun Kim, and Chi Won Ahn

Subjects
Nanopore, Materials science, Clinical Biochemistry, Human immunodeficiency virus (HIV), medicine, Solid-state, Nanotechnology, Cover (algebra), medicine.disease_cause, Biochemistry, Analytical Chemistry, Characterization (materials science)
Published
2019

8. Mechanical characterization of HIV-1 with a solid-state nanopore sensor

Author

Gaurav Goyal, Irwin Chaiken, Jung Soo Lee, Y. M. Nuwan D. Y. Bandara, Ramalingam Venkat Kalyana Sundaram, Min Jun Kim, Jugal Saharia, Armin Darvish, Prashanta Dutta, Chi Won Ahn, Jungsuk Kim, and Bin Peng

Subjects
viruses, Clinical Biochemistry, 02 engineering and technology, 01 natural sciences, Biochemistry, Virus, Article, Analytical Chemistry, Membrane Lipids, Nanopores, Viral envelope, Infectivity, Fusion, Chemistry, 010401 analytical chemistry, Virion, Electrochemical Techniques, Viral membrane, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Biomechanical Phenomena, Nanopore, Membrane, Cholesterol, Membrane protein, Biophysics, HIV-1, 0210 nano-technology
Abstract

Enveloped viruses fuse with cells to transfer their genetic materials and infect the host cell. Fusion requires deformation of both viral and cellular membranes. Since the rigidity of viral membrane is a key factor in their infectivity, studying the rigidity of viral particles is of great significance in understating viral infection. In this paper, a nanopore is used as a single molecule sensor to characterize the deformation of pseudo-type human immunodeficiency virus type 1 at sub-micron scale. Non-infective immature viruses were found to be more rigid than infective mature viruses. In addition, the effects of cholesterol and membrane proteins on the mechanical properties of mature viruses were investigated by chemically modifying the membranes. Furthermore, the deformability of single virus particles was analyzed through a recapturing technique, where the same virus was analyzed twice. The findings demonstrate the ability of nanopore resistive pulse sensing to characterize the deformation of a single virus as opposed to average ensemble measurements.

Published
2018

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