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1. Peptide-Decorated Microneedles for the Detection of Microplastics

Author

Suyeon Ahn, Namju Kim, Yonghyun Choi, Jiwon Kim, Hyeryun Hwang, Cholong Kim, Hee-Young Lee, Seungyoun Kim, Jin Su Kim, Hyun Ho Lee, and Jonghoon Choi

Subjects
microplastic, peptide, microneedle, Raman spectroscopy, Biotechnology, TP248.13-248.65
Abstract

The escalating utilization of plastics in daily life has resulted in pervasive environmental pollution and consequent health hazards. The challenge of detecting and capturing microplastics, which are imperceptible to the naked eye, is exacerbated by their diminutive size, hydrophobic surface properties, and capacity to absorb organic compounds. This study focuses on the application of peptides, constituted of specific amino acid sequences, and microneedles for the rapid and selective identification of microplastics. Peptides, due to their smaller size and greater environmental stability compared with antibodies, emerge as a potent solution to overcome the limitations inherent in existing detection methodologies. To immobilize peptides onto microneedles, this study employed microneedles embedded with gold nanorods, augmenting them with sulfhydryl (SH) groups at the peptides’ termini. The sensor developed through this methodology exhibited efficient peptide binding to the microneedle tips, thereby facilitating the capture of microplastics. Raman spectroscopy was employed for the detection of microplastics, with the results demonstrating successful attachment to the microneedles. This novel approach not only facilitates localized analysis but also presents a viable strategy for the detection of microplastics across diverse environmental settings.

Published
2024
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2. Characteristics of Synaptic Function of Mesoporous Silica–Titania and Mesoporous Titania Lateral Electrode Devices

Author

Dhanashri Vitthal Desai, Jongmin Yang, and Hyun Ho Lee

Subjects
mesoporous silica titania, synaptic device, rectification, neuromorphic electronics, Chemistry, QD1-999
Abstract

In this paper, we have fabricated non-volatile memory resistive switching (RS) devices and analyzed analog memristive characteristics using lateral electrodes with mesoporous silica–titania (meso-ST) and mesoporous titania (meso-T) layers. For the planar-type device having two parallel electrodes, current–voltage (I–V) curves and pulse-driven current changes could reveal successful long-term potentiation (LTP) along with long-term depression (LTD), respectively, by the RS active mesoporous two layers for 20~100 μm length. Through mechanism characterization using chemical analysis, non-filamental memristive behavior unlike the conventional metal electroforming was identified. Additionally, high performance of the synaptic operations could be also accomplished such that a high current of 10−6 Amp level could occur despite a wide electrode spacing and short pulse spike biases under ambient condition with moderate humidity (RH 30~50%). Moreover, it was confirmed that rectifying characteristics were observed during the I–V measurement, which was a representative feature of dual functionality of selection diode and the analog RS device for both meso-ST and meso-T devices. The memristive and synaptic functions along with the rectification property could facilitate a chance of potential implementation of the meso-ST and meso-T devices to neuromorphic electronics platform.

Published
2023
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3. Aged G Protein-Coupled Receptor Kinase 3 (Grk3)-Deficient Mice Exhibit Enhanced Osteoclastogenesis and Develop Bone Lesions Analogous to Human Paget’s Disease of Bone

Author

Emily M. Rabjohns, Rishi R. Rampersad, Arin Ghosh, Katlyn Hurst, Amanda M. Eudy, Jaime M. Brozowski, Hyun Ho Lee, Yinshi Ren, Anthony Mirando, Justin Gladman, Jessica L. Bowser, Kathryn Berg, Sachin Wani, Stuart H. Ralston, Matthew J. Hilton, and Teresa K. Tarrant

Subjects
bone, osteoclast, Paget’s, Paget’s disease of bone, G protein-coupled receptor kinase, G protein-coupled receptor, Cytology, QH573-671
Abstract

Paget’s Disease of Bone (PDB) is a metabolic bone disease that is characterized by dysregulated osteoclast function leading to focal abnormalities of bone remodeling. It can lead to pain, fracture, and bone deformity. G protein-coupled receptor kinase 3 (GRK3) is an important negative regulator of G protein-coupled receptor (GPCR) signaling. GRK3 is known to regulate GPCR function in osteoblasts and preosteoblasts, but its regulatory function in osteoclasts is not well defined. Here, we report that Grk3 expression increases during osteoclast differentiation in both human and mouse primary cells and established cell lines. We also show that aged mice deficient in Grk3 develop bone lesions similar to those seen in human PDB and other Paget’s Disease mouse models. We show that a deficiency in Grk3 expression enhances osteoclastogenesis in vitro and proliferation of hematopoietic osteoclast precursors in vivo but does not affect the osteoclast-mediated bone resorption function or cellular senescence pathway. Notably, we also observe decreased Grk3 expression in peripheral blood mononuclear cells of patients with PDB compared with age- and gender-matched healthy controls. Our data suggest that GRK3 has relevance to the regulation of osteoclast differentiation and that it may have relevance to the pathogenesis of PDB and other metabolic bone diseases associated with osteoclast activation.

Published
2023
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4. Nitrous oxide emission from upland soil amended with different animal manures

Author

Sung Un Kim, Chuanpit Ruangcharus, Sandeep Kumar, Hyun Ho Lee, Hye Jin Park, Eun Sang Jung, and Chang Oh Hong

Subjects
Denitrification, Greenhouse gas, Nitrification, Nitrogen use, Sweet potato, Agriculture (General), S1-972, Chemistry, QD1-999
Abstract

Abstract The nitrous oxide (N2O) emission of from arable soil following the application of manure is expected to vary by different animal manure types used. This study was conducted to determine the relationship between the type of animal manure used to amend soil and the amount of N2O emitted during the cultivation of sweet potato (Ipomoea batatas). An additional objective was to study the characteristics of nitrogen (N) and carbon (C) in different animal manures. Composted manures from chickens, cows, and pigs were applied to the soil at rates of 0, 10, and 20 Mg ha−1, respectively. The availability and concentration of N and C varied by manure type. The concentration of NH4 + was greater in pig manure (4638 mg kg−1) than in chicken (551 mg kg−1) and cow manure (147 mg kg−1). The mean cumulative N2O emission rate across soil application rates was also the highest with pig manure (11.9 kg ha−1 year−1), followed by chicken and cow manure, with emission rates of 10.8 and 10.1 kg ha−1 year−1, respectively. The majority of N2O measured during the sweet-potato-growing season was produced from aerobic nitrification. Dissolved organic carbon (DOC) concentrations in animal manures did not affect cumulative N2O emission rates, and no significant relationship was observed throughout the growing season between the concentration of DOC in soil and daily N2O emission. Cumulative N2O emission rates depended on the type of animal manure and might be governed by NH4 + concentration, rather than by total N concentration in animal manure type.

Published
2019
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5. Do Metals Increase or Decrease Nitrous Oxide Emissions and Maize Yields from Upland Soils?

Author

Ye Lim Park, Hyun Ho Lee, Sung Un Kim, Namgoo Kang, and Chang Oh Hong

Subjects
denitrification, greenhouse gas, micronutrient, nitrification, water-filled pore space, Agriculture (General), S1-972
Abstract

Metals, including copper (Cu), iron (Fe), and zinc (Zn), are associated with nitrous oxide (N2O) production processes, such as nitrification and denitrification. This study aimed to elucidate the effects of Cu, Fe, and Zn on N2O emissions and to determine cumulative N2O emission and crop yields from upland soils. Metals were applied at a rate of 20 kg ha−1 in upland soil supporting maize (Zea mays L.) growth in 2018 and 2019. While the mean value of cumulative N2O emissions across both years was 5.19 kg N2O ha−1 yr−1 for the control soil, those of soil treated with Cu, Fe, and Zn were 3.37, 2.48, and 4.82 kg N2O ha−1 yr−1, respectively. Ammonium (NH4+) concentration in soil was highest after Fe application, and nitrate (NO3−) concentration was lowest. The copy number of the amoA gene related to NH4+ oxidation was lowest after Fe enhancement, implying that nitrification was inhibited. Furthermore, N2O emission decreased with Cu addition because the copy number of the nosZ gene associated with N2O reduction to N2 was the highest. Because Cu and Fe decreased yield-scaled N2O emission, the application of either metal could reduce N2O emission per unit area of maize production, suggesting that both metals are beneficial soil amendments for reducing N2O emissions while maintaining maize yield.

Published
2022
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6. Peptide Specific Nanoplastic Detection Based on Sandwich Typed Localized Surface Plasmon Resonance

Author

Seungju Oh, Hyeyeon Hur, Yoonjae Kim, Seongcheol Shin, Hyunjeong Woo, Jonghoon Choi, and Hyun Ho Lee

Subjects
nanoplastics, LSPR, peptide binding, sandwich assay, Chemistry, QD1-999
Abstract

Recently, various waste microplastics sensors have been introduced in response to environmental and biological hazards posed by waste microplastics. In particular, the detrimental effects of nano-sized plastics or nanoplastics have been reported to be severe. Moreover, there have been many difficulties for sensing microplastics due to the limited methodologies for selectively recognizing nanoplastics. In this study, a customized gold nanoparticles (Au NPs) based localized surface plasmon resonance (LSPR) system having bio-mimicked peptide probes toward the nanoplastics was demonstrated. The specific determination through the oligo-peptide recognition was accomplished by chemical conjugation both on the LSPR chip’s 40~50 nm Au NPs and sandwiched 5 nm Au NPs, respectively. The peptide probe could selectively bind to polystyrene (PS) nanoplastics in the forms of fragmented debris by cryo-grinding. A simple UV-Vis spectrophotometer was used to identify the LSPR sensing by primarily measuring the absorbance change and shift of absorption peak. The sandwich-binding could increase the LSPR detection sensitivity up to 60% due to consecutive plasmonic effects. In addition, microwave-boiled DI water inside of a styrofoam container was tested for putative PS nanoplastics resource as a real accessible sample. The LSPR system could be a novel protocol overcoming the limitations from conventional nanoplastic detection.

Published
2021
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7. Highly Sensitive Colorimetric Assay of Cortisol Using Cortisol Antibody and Aptamer Sandwich Assay

Author

Yoonjae Kim, Jongmin Yang, Hyeyeon Hur, Seungju Oh, and Hyun Ho Lee

Subjects
cortisol, c-Mab, c-SBA, antibody aptamer sandwich, colorimetric assay, Biotechnology, TP248.13-248.65
Abstract

In this study, cortisol, which is a key stress hormone, could be detected sensitively via the colorimetric assay of a polycarbonate (PC) and glass substrate by the sandwich assay of cortisol monoclonal antibody (c-Mab) and cortisol specific binding aptamer (c-SBA). A highly sensitive change in colorimetry with a limit of detection (LOD) of cortisol of 100 fM could be attained on the optically transparent substrate using the antibody aptamer sandwich (AAS) assay by corresponding stacks of 5 nm gold nanoparticles (Au NPs). The Au NPs were conjugated by the c-SBA and the c-Mab was tethered on the PC and glass substrates. For the AAS method, a simple UV-Vis spectrophotometer was adopted to quantify the cortisol concentrations at an absorbance wavelength of 520 nm. Therefore, this study demonstrates the versatility of the AAS method to measure very low concentrations of cortisol in diagnostic applications.

Published
2021
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8. Analog Memristive Characteristics of Square Shaped Lanthanum Oxide Nanoplates Layered Device

Author

Wonkyu Kang, Kyoungmin Woo, Hyon Bin Na, Chi Jung Kang, Tae-Sik Yoon, Kyung Min Kim, and Hyun Ho Lee

Subjects
analog resistive switching, square shape, lanthanum oxide, neuromorphic device, Chemistry, QD1-999
Abstract

Square-shaped or rectangular nanoparticles (NPs) of lanthanum oxide (LaOx) were synthesized and layered by convective self-assembly to demonstrate an analog memristive device in this study. Along with non-volatile analog memory effect, selection diode property could be co-existent without any implementation of heterogeneous multiple stacks with ~1 μm thick LaOx NPs layer. Current–voltage (I–V) behavior of the LaOx NPs resistive switching (RS) device has shown an evolved current level with memristive behavior and additional rectification functionality with threshold voltage. The concurrent memristor and diode type selector characteristics were examined with electrical stimuli or spikes for the duration of 10–50 ms pulse biases. The pulsed spike increased current levels at a read voltage of +0.2 V sequentially along with ±7 V biases, which have emulated neuromorphic operation of long-term potentiation (LTP). This study can open a new application of rare-earth LaOx NPs as a component of neuromorphic synaptic device.

Published
2021
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9. Mobility Models Based on Forward Current-Voltage Characteristics of P-type Pseudo-Vertical Diamond Schottky Barrier Diodes

Author

Min-Woo Ha, Ogyun Seok, Hojun Lee, and Hyun Ho Lee

Subjects
diamond, Schottky barrier diode, power device, hole mobility, forward current, Mechanical engineering and machinery, TJ1-1570
Abstract

Compared with silicon and silicon carbide, diamond has superior material parameters and is therefore suitable for power switching devices. Numerical simulation is important for predicting the electric characteristics of diamond devices before fabrication. Here, we present numerical simulations of p-type diamond pseudo-vertical Schottky barrier diodes using various mobility models. The constant mobility model, based on the parameter μconst, fixed the hole mobility absolutely. The analytic mobility model resulted in temperature- and doping concentration-dependent mobility. An improved model, the Lombard concentration, voltage, and temperature (CVT) mobility model, considered electric field-dependent mobility in addition to temperature and doping concentration. The forward voltage drop at 100 A/cm2 using the analytic and Lombard CVT mobility models was 2.86 and 5.17 V at 300 K, respectively. Finally, we used an empirical mobility model based on experimental results from the literature. We also compared the forward voltage drop and breakdown voltage of the devices, according to variations in p- drift layer thickness and cathode length. The device successfully achieved a low specific on-resistance of 6.8 mΩ∙cm2, a high breakdown voltage of 1190 V, and a high figure-of-merit of 210 MW/cm2.

Published
2020
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10. A Nanopore Structured High Performance Toluene Gas Sensor Made by Nanoimprinting Method

Author

Yong-Sang Kim, Chi Jung Kang, Hyun Ho Lee, Tae-Sik Yoon, Jung-Min Kim, Kwang-Su Kim, and Woon-Hyuk Baek

Subjects
toluene, gas sensor, MIS structure, nanoimprinting method, titania, nanopore, Chemical technology, TP1-1185
Abstract

Toluene gas was successfully measured at room temperature using a device microfabricated by a nanoimprinting method. A highly uniform nanoporous thin film was produced with a dense array of titania (TiO2) pores with a diameter of 70~80 nm using this method. This thin film had a Pd/TiO2 nanoporous/SiO2/Si MIS layered structure with Pd-TiO2 as the catalytic sensing layer. The nanoimprinting method was useful in expanding the TiO2 surface area by about 30%, as confirmed using AFM and SEM imaging. The measured toluene concentrations ranged from 50 ppm to 200 ppm. The toluene was easily detected by changing the Pd/TiO2 interface work function, resulting in a change in the I-V characteristics.

Published
2010
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18. The increase in N fertilizer application is the key to solving the problem of food security and global warming in rice paddy soils with high initial N concentrations

Author

Hyun Ho Lee, Eun Jung Choi, Ok Jung Ju, Chang Oh Hong, and Hojeong Kang

Abstract

It is essential to reduce methane (CH4) emissions to minimize the contribution of global warming from rice paddies because CH4 contributes approximately 87% to the global warming potential (GWP). An increase in N fertilizer application could reduce CH4 emissions for several reasons: (1) affect the biomass enhancement of crops to store carbon, (2) decrease methanogenesis activity due to increased nitrate respiration, (3) occur nitrate- and nitrite-dependent anaerobic CH4 oxidation. According to the global scale meta-analysis, increasing N application reduces CH4 emissions. However, the reducing effect of nitrogen (N) fertilization on CH4 emissions from rice paddies needs to be confirmed. The changes in CH4 emission induced by N have a reasonably wide margin of error because the research results were not controlled for the direct factors related to CH4 emissions. Hence, although the increased N fertilizer can increase crop productivity and reduce GWP, it is not introduced as an appropriate agricultural practice. To elucidate the effects of N fertilization on CH4 emissions from rice paddies, field-based manipulation experiments were conducted in three regions where N fertilizer was applied under the control of the other factors. In addition, we aimed to identify why CH4 emissions differ depending on the amount of N fertilizer through the result of the microbial-mediated CH4 cycle.Urea was selected as N fertilizer and application rates were at 0, 90, 135, and 180 kg ha-1 (N0, N1, N2, and N3, respectively). Irrigation, rice species (Oryza sativa cv. Samkwang), cultivation period, and input of P, K, Ca, and Si fertilizer were identically managed in 3 sites in Miryang, Wanju, and Hwaseong for three years. DNA/RNA co-extraction was performed using three region’s soil samples in the 3rd year. Real-time qPCR was performed to quantify the mcrA and pmoA gene copy numbers to identify the abundances of methanogens and methanotrophs, respectively.Cumulative CH4 emissions increased with increasing N fertilizer in Miryang. In contrast, cumulative CH4 emissions significantly decreased with increasing N fertilizer application rates in Hwaseong and Wanju. Especially, N2 and N3 showed CH4 emissions lower than N0 in Hwaseong. In Wanju, the decrease in the abundance of mcrA and subsequently methanogenesis after N1 may cause a reduction in CH4 emissions, while in Hwaseong, the increase in quantification of pmoA and the subsequent higher CH4 oxidation may induce a decline in CH4 emissions. In Miryang, higher mcrA may promote methanogenesis and higher CH4 emissions with an increasing N application. The different responses in methanogens and methanotrophs with different N fertilizer application rates could be due to the initial N concentration. The correlation analysis between initial N including ammonium and nitrate and CH4 emissions from the literature showed a negative relationship at a global scale, suggesting the mechanism based on our experimental results is robust in global rice paddies.In conclusion, additional N fertilizer application considering the initial N concentration can not only increase crop yield in rice paddies but also reduce global warming by reducing CH4 emissions.

Published
2023
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47. Blast Loading Profile of Gaseous Hydrogen in Confined Space Under Various Leak Conditions

Author

Seon Jin Kim, Hyun Ho Lee, Soung Woo Park, Dae Yu Baeg, Jeong Hwan Kim, and Jung Kwan Seo

Abstract

Research on hydrogen facilities in the shipbuilding industry and on hydrogen fuel ships and carriers is growing due to the depletion of fossil fuels and the increasingly strict regulation of environmental pollution. Compared with hydrocarbon-based fuels, hydrogen fuel has low minimum ignition energy and a wide-ranging flammability limit. Therefore, before utilizing hydrogen energy, hazard assessment studies of hydrogen leakage and explosion must be performed to ensure safety. It is hazardous to the release of gaseous hydrogen into confined spaces, such as storage and engine rooms of ships, because the hydrogen gas cloud, which is less dense than air, stagnates and accumulates near the ceiling. The main objective of this study is to examine the effects of gaseous hydrogen leakage conditions in confined spaces on the behavior of flammable gas cloud and blast loading profile. To analyze hydrogen gas cloud behavior, hydrogen release experiments were conducted in a 1.0 m × 1.0 m × 3.0 m enclosure at various leak nozzle heights (0.3, 1.5, and 2.7 m) and leak rates (100, 200, and 300 L/min). The results of hydrogen leakage experiments, the flammable gas cloud volume were found to increase with increasing leakage rate and decreasing leakage nozzle height. Due to the lack of the number of concentration sensors, there was a limit to the analysis of all the concentration field of hydrogen in the enclosure. All flammable concentration fields in the enclosure were evaluated and compared using FLACS, the computational fluid dynamics simulation software. In addition, the effects of ignition heights on hydrogen blast loading were analyzed using FLACS. The simulation revealed that a high hydrogen leak rate and a far leak nozzle-ceiling distance tends to result in a large gas cloud volume, which in turn results in high peak pressure and impulse. The highest overpressure and impulse were approximately 5 barg and 39 kPa·s, respectively. These results suggest that in confined spaces, equipment with high potential for hydrogen leakage (e.g., pipes) should not be designed near the ground. This paper thus contributes to the design standard for hydrogen storage facilities in confined spaces (e.g., ships) and lays the foundation for establishing a standard for marginal safety blast walls for protection from hydrogen explosions.

Published
2022
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48. Prediction of Inclined Surface Spreading Extent for High Flashpoint Fuel in Large Compartments Under Ship Motion

Author

Dae Yu Baeg, Hyun Ho Lee, Seung Yul Lee, Seon Jin Kim, Jeong Hwan Kim, and Jung Kwan Seo

Abstract

Fire accidents can occur on in-service ships and offshore installations due to the spillage of fuels from components such as storage tanks and valves under accidental and extreme conditions. In such accidents, the liquefied fuel spread area on the decks are affected by ship motion and properties of the fuel, which may cause a pool fire to develop into a large-scale fire, resulting in casualties and severe damage to property and the environment. Therefore, the effects of surface spread extent on the structural response of ships and offshore installations should be examined. Additional safety measures are particularly necessary on ships with large compartments, such as Ro-Ro ships. However, these fire hazards and their preventive measures have not been sufficiently explored. Thus, in this study, fuel discharge experiments were conducted to investigate the fuel spreading behavior at different substrate slopes and discharge rates. Based on the results, empirical formulae that predict the spreading extent of liquefied fuel in large compartments were derived. Additionally, the proposed formulae were used to investigate the variation of heat release rate in different spillage scenarios.

Published
2022
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