Kyo Seon Hwang

Detection of Hepatitis B Virus (HBV) DNA at femtomolar concentrations using a silica nanoparticle-enhanced microcantilever sensor.

We report Hepatitis B Virus (HBV) DNA detection using a silica nanoparticle-enhanced dynamic microcantilever biosensor. A 243-mer nucleotide of HBV DNA precore/core region was used as the target DNA. For this assay, the capture probe on the microcantilever surface and the detection probe conjugated with silica nanoparticles were designed specifically for the target DNA. For efficient detection of the HBV target DNA using silica nanoparticle-enhanced DNA assay, the size of silica nanoparticles and the dimension of microcantilever were optimized by directly binding the silica nanoparticles through DNA hybridization. In addition, the correlation between the applied nanoparticle concentrations and the resonant frequency shifts of the microcantilever was discussed clearly to validate the quantitative relationship between mass loading and resonant frequency shift. HBV target DNAs of 23.1 fM to 2.31 nM which were obtained from the PCR product were detected using a silica nanoparticle-enhanced microcantilever. The HBV target DNA of 243-mer was detected up to the picomolar (pM) level without nanoparticle enhancement and up to the femtomolar (fM) level using a nanoparticle-based signal amplification process. In the above two cases, the resonant frequency shifts were found to be linearly correlated with the concentrations of HBV target DNAs. We believe that this linearity originated mainly from an increase in mass that resulted from binding between the probe DNA and HBV PCR product, and between HBV PCR product and silica nanoparticles for the signal enhancement, even though there is another potential factor such as the spring constant change that may have influenced on the resonant frequency of the microcantilever.

Dominant surface stress driven by biomolecular interactions in the dynamical response of nanomechanical microcantilevers

Nanomechanical microcantilevers have played a vital role in detecting biomolecular interactions. The ability of microcantilevers to detect biomolecular interactions is ascribed to the principle that the surface stress, caused by biomolecular interactions, dominates the dynamical response of the microcantilever. Here we have experimentally studied the correlation between biomolecular interactions and the dynamical response of microcantilevers. Moreover, the authors employed a mechanical beam model to calculate the surface stress, representing the biomolecular interactions, through measuring the resonant frequency shift. The quantitative analysis of surface stress, driven by the specific protein-protein interactions, demonstrated that microcantilevers enable the quantitative study of biomolecular interactions.

Peptide receptor-based selective dinitrotoluene detection using a microcantilever sensor.

We reported that peptide could be utilized as receptor molecule in the gas phase for application in micro/nano sensors by using a specific peptide that recognizes 2,4-dinitrotoluene at room temperature and in an atmospheric environment and measuring changes in the resonant frequency of the peptide immobilized microcantilevers. By using these peptides as receptors on a microcantilever sensor, we were able to experimentally detect 2,4-dinitrotoluene (DNT) vapor at concentrations as low as parts per billion (ppb) in the gas phase. While resonant frequency changes after binding between 2,4-DNT and the specific peptide receptor that was immobilized on microcantilevers were observed, the resonant frequency of DNT nonspecific peptide immobilized microcantilever did not change when exposed to 2,4-DNT vapor. The limit of detection (LOD) was calculated to be 431 ppt of limit of detection is numerically expected by experimental based on an equation that describes the relationship between the noise-equivalent analyte concentration. These results indicate that the peptide receptors hold great promise for use in the development of an artificial olfactory system and electronic nose based on micro/nanotechnology for monitoring various chemical vapors in the gas phase such as explosive mixtures of chemicals and/or volatile organic compounds.

Microstructure and adhesion of Au deposited on parylene-c substrate with surface modification for potential immunoassay application

Improvement of recrystallization and adhesion of gold (Au) deposited on parylene-c (Pa-c) substrate with heat treatment and surface modification using physical and chemical treatment was investigated. Annealing of Au on Pa-c was performed to observe microstructure enhancement due to heat treatment from 100 to 250/spl deg/C. From the peak intensity and full-width at half-maximum of Au(111), its crystallinity appeared to improve as the annealing temperature increased, which can provide the surface with proper creation of monolayers. Several physical and chemical methods of surface modifications were employed to analyze surface energy and adhesion promotion, such as oxygen plasma, atmospheric plasma, ion beam, and Bovine serum albumin. These results exhibit excellent adhesion properties by exploiting oxygen plasma and ion-beam treatment, which induce carbonyl groups via the mechanical interlocking.

Simple and Highly Sensitive Molecular Diagnosis of Zika Virus by Lateral Flow Assays

We have developed a simple, user-friendly, and highly sensitive Zika virus (ZIKV) detection method by incorporating optimized reverse transcription loop-mediated isothermal amplification (RT-LAMP) and a lateral flow assay (LFA). The optimized RT-LAMP reaction was carried out using Bst 3.0 polymerase, which has robust and fast isothermal amplification performance even in the presence of high concentrations of inhibitors; this permitted the amplification of ZIKV RNA in pure water and human whole blood. In addition, the strong reverse transcription activity of Bst 3.0 polymerase enabled specific ZIKV RNA amplification without extra addition of reverse transcriptase. The RT-LAMP condition was optimized by adjusting the Mg2+ and dNTP mix concentration to extirpate nontarget amplification, which is caused by nonspecific primer dimers amplification. After 30 min of RT-LAMP reaction, the resultant amplicons were simply and rapidly analyzed by the LFA test in less than 5 min. The optimized RT-LAMP combined with the LFA allowed specific ZIKV RNA detection down to the single copy level within 35 min.

Enhancing surface functionality of reduced graphene oxide biosensors by oxygen plasma treatment for Alzheimer's disease diagnosis

We performed oxygen plasma treatment on reduced graphene oxide (rGO) to improve its surface reactivity with respect to biomolecular interactions. Oxygen-plasma-treated rGO surfaces were employed as reactive interfaces for the detection of amyloid-beta (Aβ) peptides, the pathological hallmarks of Alzheimers disease (AD), as the target analytes. By measuring the changes in electrical characteristics and confirmation through topographic analysis, the oxygen-plasma-treated rGO sensors had enhanced surface functionality for better antibody immobilization and sensing performance, with a 3.33-fold steeper slope for the electrical responses versus analyte concentration curve (logarithmic scale) compared to the untreated. The elicited biomolecular reactivity of the rGO surfaces with the oxygen plasma treatment remained at 46-51% of the initial value even after aging for 6h in ambient conditions. This phenomenon was also confirmed by pretreating the rGO surfaces with a blocking agent and subsequently subjecting them to antibody immobilization. Finally, the feasibility of the oxygen-plasma-treated rGO sensors as a diagnostic tool was evaluated with clinical samples of neural-derived exosomal Aβ peptides extracted from apparent AD patients and normal controls (NC). In contrast to the untreated sensors (p=0.0460), the oxygen-plasma-treated rGO sensors showed a significant p-value in the identification of clinical samples of AD and NC subjects (p<0.001). These results suggest that oxygen plasma treatment improves sensor performance without complicated fabrication procedures and should aid in the development of novel diagnostic tools based on carbon nanomaterials.

Multifunctionalized cantilever systems for electronic nose applications.

Multiple target detection using a cantilever is essential for biosensor, chemical sensor, and electronic nose systems. We report a novel microcantilever array chip that includes four microreaction chambers in a chip, which consequently contains four different functionalized surfaces for multitarget detection. For model tests, we designed microcantilever chips and demonstrated the ability of binding of 2,4-dinitrotoluene (DNT) targets onto four different surfaces. We used peptide receptors that are known to have highly selective binding. By simply using four microreaction chambers, we immobilized DNT specific peptide (HPNFSKYILHQRC; SP), DNT nonspecific peptide (TSMLLMSPKHQAC; NSP), and self-assembled monolayer (SAM) as well as a bare cantilever. After flowing DNT gases through the cantilever chip, we could monitor the four different binding signals simultaneously. The shifts in NSP provided information as a negative control because it contained information of temperature fluctuations and mechanical vibration from gas flow. By utilizing the differential signal of the SP and NSP, we acquired 7.5 Hz in resonant responses that corresponds with 160 part per billion (ppb) DNT concentration, showing the exact binding response by eliminating the inevitable thermal noise, vibration noise, as well as humidity effects on the peptide surface.

Microstress relaxation effect of Pb(Zr0.52Ti0.48)O3 films with thicknesses for micro/nanopiezoelectric device

In this study, we analyzed the microstress of Pb(Zr0.52Ti0.48)O3 (PZT) films using Raman spectrum and the macrostress using the wafer curvature method. Based on the stress analysis, we also determined the relationship between the residual stress and piezoelectric properties. We found that a thickness of 1 μm was critical since the stress relaxation starts due to surface roughening. Similarly, the film thickness dependence of the piezoelectric coefficient had saturation values around 1 μm, where the preferred orientation started to change from (111) to (110), indicating that the piezoelectric response was related to the stress relaxation with a preferred orientation change.

Sensitivity Enhancement of Bead-based Electrochemical Impedance Spectroscopy (BEIS) biosensor by electric field-focusing in microwells

This paper reports a novel electrochemical impedance spectroscopy (EIS) biosensors that uses magnetic beads trapped in a microwell array to improve the sensitivity of conventional bead-based EIS (BEIS) biosensors. Unloading the previously measured beads by removing the magnetic bar enables the BEIS sensor to be used repeatedly by reloading it with new beads. Despite its recyclability, the sensitivity of conventional BEIS biosensors is so low that it has not attracted much attentions from the biosensor industry. We significantly improved the sensitivity of the BEIS system by introducing of a microwell array that contains two electrodes (a working electrode and a counter electrode) to concentrate the electric field on the surfaces of the beads. We confirmed that the performance of the BEIS sensor in a microwell array using an immunoassay of prostate specific antigen (PSA) in PBS buffer and human plasma. The experimental results showed that a low concentration of PSA (a few tens or hundreds of fg/mL) were detectable as a ratio of the changes in the impedance of the PBS buffer or in human plasma. Therefore, our BEIS sensor with a microwell array could be a promising platform for low cost, high-performance biosensors for applications that require high sensitivity and recyclability.

Single-carbon discrimination by selected peptides for individual detection of volatile organic compounds

Although volatile organic compounds (VOCs) are becoming increasingly recognized as harmful agents and potential biomarkers, selective detection of the organic targets remains a tremendous challenge. Among the materials being investigated for target recognition, peptides are attractive candidates because of their chemical robustness, divergence, and their homology to natural olfactory receptors. Using a combinatorial peptide library and either a graphitic surface or phenyl-terminated self-assembled monolayer as relevant target surfaces, we successfully selected three interesting peptides that differentiate a single carbon deviation among benzene and its analogues. The heterogeneity of the designed target surfaces provided peptides with varying affinity toward targeted molecules and generated a set of selective peptides that complemented each other. Microcantilever sensors conjugated with each peptide quantitated benzene, toluene and xylene to sub-ppm levels in real time. The selection of specific receptors for a group of volatile molecules will provide a strong foundation for general approach to individually monitoring VOCs.