Your search keyword '"Kim, Hojun"' showing total 20 results

1. A lipid nanoparticle platform incorporating trehalose glycolipid for exceptional mRNA vaccine safety

Author

Bae, Seo-Hyeon, Yoo, Soyeon, Lee, Jisun, Park, Hyo-Jung, Kwon, Sung Pil, Jin, Harin, Park, Sang-In, Lee, Yu-Sun, Bang, Yoo-Jin, Roh, Gahyun, Lee, Seonghyun, Youn, Sue Bean, Kim, In Woo, Oh, Ho Rim, El-Damasy, Ashraf K., Keum, Gyochang, Kim, Hojun, Youn, Hyewon, Nam, Jae-Hwan, and Bang, Eun-Kyoung

Abstract

The rapid development of messenger RNA (mRNA) vaccines formulated with lipid nanoparticles (LNPs) has contributed to control of the COVID-19 pandemic. However, mRNA vaccines have raised concerns about their potential toxicity and clinical safety, including side effects, such as myocarditis, anaphylaxis, and pericarditis. In this study, we investigated the potential of trehalose glycolipids-containing LNP (LNP S050L) to reduce the risks associated with ionizable lipids. Trehalose glycolipids can form hydrogen bonds with polar biomolecules, allowing the formation of a stable LNP structure by replacing half of the ionizable lipids. The efficacy and safety of LNP S050L were evaluated by encapsulating the mRNA encoding the luciferase reporter gene and measuring gene expression and organ toxicity, respectively. Furthermore, mice immunized with an LNP S050L-formulated mRNA vaccine expressing influenza hemagglutinin exhibited a significant reduction in organ toxicity, including in the heart, spleen, and liver, while sustaining gene expression and immune efficiency, compared to conventional LNPs (Con-LNPs). Our findings suggest that LNP S050L, a trehalose glycolipid-based LNP, could facilitate the development of safe mRNA vaccines with improved clinical safety.

Published

2024

2. Noninvasive Precision Screening of Prostate Cancer by Urinary Multimarker Sensor and Artificial Intelligence Analysis

Author

Kim, Hojun, Park, Sungwook, Jeong, In Gab, Song, Sang Hoon, Jeong, Youngdo, Kim, Choung-Soo, and Lee, Kwan Hyi

Abstract

Screening for prostate cancer relies on the serum prostate-specific antigen test, which provides a high rate of false positives (80%). This results in a large number of unnecessary biopsies and subsequent overtreatment. Considering the frequency of the test, there is a critical unmet need of precision screening for prostate cancer. Here, we introduced a urinary multimarker biosensor with a capacity to learn to achieve this goal. The correlation of clinical state with the sensing signals from urinary multimarkers was analyzed by two common machine learning algorithms. As the number of biomarkers was increased, both algorithms provided a monotonic increase in screening performance. Under the best combination of biomarkers, the machine learning algorithms screened prostate cancer patients with more than 99% accuracy using 76 urine specimens. Urinary multimarker biosensor leveraged by machine learning analysis can be an important strategy of precision screening for cancers using a drop of bodily fluid.

Published

2021

3. Unimolecular Polypeptide Micelles via Ultrafast Polymerization of N-Carboxyanhydrides

Author

Lv, Shixian, Kim, Hojun, Song, Ziyuan, Feng, Lin, Yang, Yingfeng, Baumgartner, Ryan, Tseng, Kuan-Ying, Dillon, Shen J., Leal, Cecilia, Yin, Lichen, and Cheng, Jianjun

Abstract

Polypeptide micelles are widely used as biocompatible nanoplatforms but often suffer from their poor structural stability. Unimolecular polypeptide micelles can effectively address the structure instability issue, but their synthesis with uniform structure and well-controlled and desired sizes remains challenging. Herein we report the convenient preparation of spherical unimolecular micelles through dendritic polyamine-initiated ultrafast ring-opening polymerization of N-carboxyanhydrides (NCAs). Synthetic polypeptides with exceptionally high molecular weights (up to 85 MDa) and low dispersity (Đ< 1.05) can be readily obtained, which are the biggest synthetic polypeptides ever reported. The degree of polymerization was controlled in a vast range (25–3200), giving access to nearly monodisperse unimolecular micelles with predictable sizes. Many NCA monomers can be polymerized using this ultrafast polymerization method, which enables the incorporation of various structural and functional moieties into the unimolecular micelles. Because of the simplicity of the synthesis and superior control over the structure, the unimolecular polypeptide micelles may find applications in nanomedicine, supermolecular chemistry, and bionanotechnology.

Published

2020

4. The structural fate of lipid nanoparticles in the extracellular matrixElectronic supplementary information (ESI) available. See DOI: 10.1039/c9mh00835g

Author

Bandara, Sarith R., Molley, Thomas G., Kim, Hojun, Bharath, Priyalini A., Kilian, Kristopher A., and Leal, Cecilia

Abstract

Drug-loaded liposomes are the most successful nanomedicine to date, with multiple FDA-approved systems for a myriad of diseases. While liposome circulation time in blood and retention in tissues have been studied in detail, the structural fate of liposomes—and nanoparticles in general—in the body has not been extensively investigated. Here, we explore the interactions of liposomes with synthetic and natural hydrogel materials to understand how the natural extracellular matrix influences liposome structural characteristics. Small angle X-ray scattering, confocal microscopy, and cryogenic transmission electron microscopy data demonstrate that poly(ethylene glycol) (PEG), gelatin, alginate, and Matrigel® hydrogels cause 200 nm liposomes of 1,2-dioleoyl-sn-glycero-3-phosphocholine (DOPC) to transform into micrometer-sized aggregates. These aggregates are composed of multilamellar vesicles around 100 nm in diameter with a mean interlamellar separation of 5.5 nm. Protecting the liposomes with a corona of PEG damps this restructuring effect, making the multilamellar vesicles less stable. We attribute this unilamellar to multilamellar transition to an osmotic driving force from the hydrogel environment. This lipid restructuring has broad ramifications in the design and use of nanomedicines, and in understanding the fate and function of natural lipid-based materials within the tissue microenvironment.

Published

2020

5. Corrections to “Selective Cell–Cell Adhesion Regulation via Cyclic Mechanical Deformation Induced by Ultrafast Nanovibrations”

Author

Son, Young Ju, Keum, Changjoon, Kim, Minsoo, Jeong, Goeen, Jin, Soyeong, Hwang, Hae Won, Kim, Hyewon, Lee, Kyungwoo, Jeon, Hojeong, Kim, Hojun, Pahk, Ki Joo, Jang, Ho Won, Sun, Jeong-Yun, Han, Hyung-Seop, Lee, Kwan Hyi, Ok, Myoung-Ryul, Kim, Yu-Chan, and Jeong, Youngdo

Published

2024

6. An Unusual Homoisoflavanone from Portulaca oleracea

Author

Lee, Jung Im, Kim, Hojun, Kong, Chang‐Suk, Jun, Hee Sook, and Seo, Youngwan

Abstract

A new homoisoflavanone from Portulaca oleracea.

Published

2019

7. Nonstop Monomer-to-Aramid Nanofiber Synthesis with Remarkable Reinforcement Ability

Author

Koo, Jun Mo, Kim, Hojun, Lee, Minkyung, Park, Seul-A, Jeon, Hyeonyeol, Shin, Sung-Ho, Kim, Seon-Mi, Cha, Hyun Gil, Jegal, Jonggeon, Kim, Byeong-Su, Choi, Bong Gill, Hwang, Sung Yeon, Oh, Dongyeop X., and Park, Jeyoung

Abstract

Aramid nanofibers (ANFs), typically produced by exfoliating aramid microfibers (Kevlar) in alkaline media, exhibit excellent mechanical properties and have therefore attracted increased attention as nanoscale building blocks. However, the preparation of aramid microfibers involves laborious and hazardous processes, which limits the industrial-scale use of ANFs. This work describes a facile and direct monomer-to-ANF synthesis via an as-synthesized intermediate low-molecular-weight poly(p-phenylene terephthalamide) (PPTA) without requiring the environmentally destructive acids and high-order shearing processes. Under the employed conditions, PPTA immediately dissociates and self-assembles into ANFs within a time period of 15 h, which is much shorter than the time of 180 h (not including the Kevlar preparation time) required for the Kevlar-to-ANF conversion. Interestingly, the fabricated ANFs exhibit nanoscale dimensions and thermoplastic polyurethane (TPU) reinforcing effects similar to those of Kevlar-derived ANFs; i.e., a 1.5-fold TPU toughness improvement and a maximum ultimate tensile strength of 84 MPa are achieved at an ANF content of only 0.04 wt %. Remarkable reinforcement ability investigated by comprehensive analytical data comes from ANFs, which disturb ordered hydrogen bonding in hard segments and induce strain hardening along the elongation pathway. Thus, the developed approach paves the way to industrial-scale production of ANFs and related nanocomposites.

Published

2019

8. Fully Packaged Portable Thin Film Biosensor for the Direct Detection of Highly Pathogenic Viruses from On-Site Samples

Author

Choi, Jaewon, Jeun, Minhong, Yuk, Seong-Su, Park, Sungwook, Choi, Jaebin, Lee, Donggeun, Shin, Hyogeun, Kim, Hojun, Cho, Il-Joo, Kim, Sang Kyung, Lee, Seok, Song, Chang Seon, and Lee, Kwan Hyi

Abstract

The thin film transistor (TFT) is a promising biosensor system with great sensitivity, label-free detection, and a quick response time. However, even though the TFT sensor has such advantageous characteristics, the disadvantages hamper the TFT sensor’s application in the clinical field. The TFT is susceptible to light, noise, vibration, and limited usage, and this significantly limits its on-site potential as a practical biosensor. Herein, we developed a fully packaged, portable TFT electrochemical biosensor into a chip form, providing both portability through minimizing the laboratory equipment size and multiple safe usages by protecting the semiconductor sensor. Additionally, a safe environment that serves as a miniature probe station minimizes the previously mentioned disadvantages, while providing the means to properly link the TFT biosensor with a portable analyzer. The biosensor was taken into a biosafety level 3 (BSL-3) laboratory setting to analyze highly pathogenic avian influenza virus (HPAIV) samples. This virus quickly accumulates within a host, and therefore, early stage detection is critical to deterring the further spread of the deadly disease to other areas. However, current on-site methods have poor limits of detection (105–106EID50/mL), and because the virus has low concentration in its early stages, it cannot be detected easily. We have compared the sample measurements from our device with virus concentration data obtained from a RT-PCR (virus range: 100–104EID50/mL) and have identified an increasing voltage signal which corresponds to increasing virus concentration.

Published

2019

9. Microfluidics Synthesis of Gene Silencing Cubosomes

Author

Kim, Hojun, Sung, Jaeuk, Chang, Yunju, Alfeche, Alana, and Leal, Cecilia

Abstract

The success of gene technologies hinges on our ability to engineer superior encapsulation and delivery vectors. Cubosomes are lipid-based nanoparticles where membranes, instead of enveloping into classic liposomes, intertwine into complex arrays of pores well-ordered in a cubic lattice. These complex nanoparticles encapsulate large contents of siRNA compared to a liposomal analogue. Importantly, the membranes that form cubosomes have intrinsic fusogenic properties that promote fast endosomal escape. Despite the great potential, traditional routes of forming cubosomes lead to particle sizes too large to fulfill the state-of-the art requirements of delivery vectors. To overcome this challenge, we utilize a microfluidic nanomanufacturing device to synthesize cubosomes and siRNA-loaded cubosomes, termed cuboplexes. Utilizing cryogenic TEM and small angle X-ray scattering we elucidate the time-resolved mechanisms in which microfluidic devices allow the production of small cubosomes and cuboplexes (75 nm) that outperform commercially available delivery vectors, as well as liposome-based systems.

Published

2018

10. Effect of the Arctic terrestrial plant Ranunculus hyperboreuson LPS-induced inflammatory response via MAPK pathways

Author

Kong, Chang-Suk, Lee, Jung Im, Karadeniz, Fatih, Kim, Hojun, and Seo, Youngwan

Abstract

The Arctic flora hosts a limited number of species due to its extreme environmental conditions which also yield novel and unique secondary metabolites from withstanding plants. Considering a lack of research on bioactivity potential of Arctic flora, Ranunculus hyperboreus, an Arctic plant, was studied for its anti-inflammatory potential as a part of ongoing research on discovering novel natural bioactive products. Solvent-based fractions (H2O, n-BuOH, 85% aq. MeOH, n-hexane) from R. hyperboreusextract were observed to decrease the elevated nitrate amount during the inflammatory response of lipopolysaccharide-induced mouse macrophage RAW264.7 cells. To some extent, treatment with fractions was able to regulate the expression and protein levels of inflammation-related enzymes, iNOS and COX-2, and pro-inflammatory cytokines, TNF-α, IL-1β, and IL-6. The most active fractions, H2O and 85% aq. MeOH, were suggested to exert their effect through suppressed activation of MAPK pathways, especially JNK. Based on the studies of same species, phenolic glycosides were suggested to be the main active ingredients. To our knowledge, this is the first report of any bioactivity of R. hyperboreuswhich could be a valuable source of natural bioactive agents against inflammation.

Published

2018

11. New precoded spatial-multiplexing for an erasure event in single frequency networks

Author

Kim, Hojun, Kim, Seyoung, Shang, Yulong, Kim, Seunghyeon, and Jung, Taejin

Abstract

In this paper, we propose a new spatial-multiplexing (SM) scheme employing an orthogonal precoder over Rayleigh-fading channels for an erasure event in single frequency networks (SFN). To optimize the precoder, the average bit error rate (BER) is evaluated and minimized through a mathematical analysis. Compared to an ordinary SM, the proposed scheme guarantees identical BER performance under non-erasure fading channels and achieves a greatly improved performance under erasure fading channels, especially for a higher erasure-ratio and SNR values. This improvement is mainly due to the increase in the diversity gain incurred by the optimized precoder over the erasure event. We also compare the performance of the proposed SM to that of the conventional constellation- rotation (CR) scheme applied to the single antenna SFN systems. The results of a computer simulation show that the performance of the new scheme is more effective than that of a conventional CR across all simulation cases.

Published

2018

12. The Association Between Temperament and Microbiota in Healthy Individuals: A Pilot Study

Author

Kim, Hojun and Park, Young-Jae

Abstract

Supplemental digital content is available in the text.

Published

2017

13. Selective Cell–Cell Adhesion Regulation via Cyclic Mechanical Deformation Induced by Ultrafast Nanovibrations

Author

Son, Young Ju, Keum, Changjoon, Kim, Minsoo, Jeong, Goeen, Jin, Soyeong, Hwang, Hae Won, Kim, Hyewon, Lee, Kyungwoo, Jeon, Hojeong, Kim, Hojun, Pahk, Ki Joo, Jang, Ho Won, Sun, Jeong-Yun, Han, Hyung-Seop, Lee, Kwan Hyi, Ok, Myoung-Ryul, Kim, Yu-Chan, and Jeong, Youngdo

Abstract

The adoption of dynamic mechanomodulation to regulate cellular behavior is an alternative to the use of chemical drugs, allowing spatiotemporal control. However, cell-selective targeting of mechanical stimuli is challenging due to the lack of strategies with which to convert macroscopic mechanical movements to different cellular responses. Here, we designed a nanoscale vibrating surface that controls cell behavior via selective repetitive cell deformation based on a poroelastic cell model. The vibrating indentations induce repetitive water redistribution in the cells with water redistribution rates faster than the vibrating rate; however, in the opposite case, cells perceive the vibrations as a one-time stimulus. The selective regulation of cell–cell adhesion through adjusting the frequency of nanovibration was demonstrated by suppression of cadherin expression in smooth muscle cells (fast water redistribution rate) with no change in vascular endothelial cells (slow water redistribution rate). This technique may provide a new strategy for cell-type-specific mechanical stimulation.

Published

2023

14. Efficacy and safety of anti-obesity herbal medicine focused on pattern identification: A systematic review and meta-analysis

Author

Park, Seohyun, Keum, Dongho, and Kim, Hojun

Published

2022

15. Cuboplexes: Topologically Active siRNA Delivery

Author

Kim, Hojun and Leal, Cecilia

Abstract

RNAi technology is currently experiencing a revival due to remarkable improvements in efficacy and viability through oligonucleotide chemical manipulations and/or viatheir packaging into nanoscale carriers. At present, there is no FDA-approved system for siRNA technology in humans. The design of the next generation of siRNA carriers requires a deep understanding of how a nanoparticle’s physicochemical properties truly impart biological stability and efficiency. For example, we now know that nanoparticles need to be sterically stabilized in order to meet adequate biodistribution profiles. At present, targeting, uptake, and, in particular, endosomal escape are among the most critical challenges impairing RNAi technologies. The disruption of endosomes encompasses membrane transformations (for example, pore formation) that cost significant elastic energy. Nanoparticle size and shape have been identified as relevant parameters impacting tissue accumulation and cellular uptake. In this paper, we demonstrate that the internal structure of lipid-based particles offers a different handle to promote endosomal membrane topological disruptions that enhance siRNA delivery. Specifically, we designed sterically stabilized lipid-based particles that differ from traditional liposomal systems by displaying highly ordered bicontinuous cubic internal structures that can be loaded with large amounts of siRNA. This system differs from traditional siRNA-containing liposomes (lipoplexes) as the particle–endosomal membrane interactions are controlled by elasticity energetics and not by electrostatics. The resulting “PEGylated cuboplex” has the ability to deliver siRNA and specifically knockdown genes with efficiencies that surpass those achieved by traditional lipoplex systems.

Published

2015

16. Influence of Panax ginsengon obesity and gut microbiota in obese middle-aged Korean women

Author

Song, Mi-Young, Kim, Bong-Soo, and Kim, Hojun

Abstract

Gut microbiota is regarded as one of the major factors involved in the control of body weight. The antiobesity effects of ginseng and its main constituents have been demonstrated, but the effects on gut microbiota are still unknown.

Published

2014

17. Stimuli-Responsive Adaptive Nanotoxin to Directly Penetrate the Cellular Membrane by Molecular Folding and Unfolding

Author

Jeong, Youngdo, Jin, Soyeong, Palanikumar, L., Choi, Huyeon, Shin, Eunhye, Go, Eun Min, Keum, Changjoon, Bang, Seunghwan, Kim, Dongkap, Lee, Seungho, Kim, Minsoo, Kim, Hojun, Lee, Kwan Hyi, Jana, Batakrishna, Park, Myoung-Hwan, Kwak, Sang Kyu, Kim, Chaekyu, and Ryu, Ja-Hyoung

Abstract

Biological nanomachines, including proteins and nucleic acids whose function is activated by conformational changes, are involved in every biological process, in which their dynamic and responsive behaviors are controlled by supramolecular recognition. The development of artificial nanomachines that mimic the biological functions for potential application as therapeutics is emerging; however, it is still limited to the lower hierarchical level of the molecular components. In this work, we report a synthetic machinery nanostructure in which actuatable molecular components are integrated into a hierarchical nanomaterial in response to external stimuli to regulate biological functions. Two nanometers core-sized gold nanoparticles are covered with ligand layers as actuatable components, whose folding/unfolding motional response to the cellular environment enables the direct penetration of the nanoparticles across the cellular membrane to disrupt intracellular organelles. Furthermore, the pH-responsive conformational movements of the molecular components can induce the apoptosis of cancer cells. This strategy based on the mechanical motion of molecular components on a hierarchical nanocluster would be useful to design biomimetic nanotoxins.

Published

2022

18. SARS-CoV-2 Variant Screening Using a Virus-Receptor-Based Electrical Biosensor

Author

Park, Sungwook, Kim, Hojun, Woo, Kyungmin, Kim, Jeong-Min, Jo, Hye-Jun, Jeong, Youngdo, and Lee, Kwan Hyi

Abstract

SARS-CoV-2 variants are of particular interest because they can potentially increase the transmissibility and virulence of COVID-19 or reduce the effectiveness of available vaccines. However, screening SARS-CoV-2 variants is a challenge because biosensors target viral components that can mutate. One promising strategy is to screen variants via angiotensin-converting enzyme 2 (ACE2), a virus receptor shared by all known SARS-CoV-2 variants. Here we designed a highly sensitive and portable COVID-19 screening biosensor based on the virus receptor. We chose a dual-gate field-effect transistor to overcome the low sensitivity of virus-receptor-based biosensors. To optimize the biosensor, we introduced a synthetic virus that mimics the important features of SARS-CoV-2 (size, bilayer structure, and composition). The developed biosensor successfully detected SARS-CoV-2 in 20 min and showed sensitivity comparable to that of molecular diagnostic tests (∼165 copies/mL). Our results indicate that a virus-receptor-based biosensor can be an effective strategy for screening infectious diseases to prevent pandemics.

Published

2021

19. Biological lipid membranes for on-demand, wireless drug delivery from thin, bioresorbable electronic implants

Author

Lee, Chi Hwan, Kim, Hojun, Harburg, Daniel V, Park, Gayoung, Ma, Yinji, Pan, Taisong, Kim, Jae Soon, Lee, Na Yeon, Kim, Bong Hoon, Jang, Kyung-In, Kang, Seung-Kyun, Huang, Yonggang, Kim, Jeongmin, Lee, Kyung-Mi, Leal, Cecilia, and Rogers, John A

Abstract

On-demand, localized release of drugs in precisely controlled, patient-specific time sequences represents an ideal scenario for pharmacological treatment of various forms of hormone imbalances, malignant cancers, osteoporosis, diabetic conditions and others. We present a wirelessly operated, implantable drug delivery system that offers such capabilities in a form that undergoes complete bioresorption after an engineered functional period, thereby obviating the need for surgical extraction. The device architecture combines thermally actuated lipid membranes embedded with multiple types of drugs, configured in spatial arrays and co-located with individually addressable, wireless elements for Joule heating. The result provides the ability for externally triggered, precision dosage of drugs with high levels of control and negligible unwanted leakage, all without the need for surgical removal. In vitro and in vivo investigations reveal all of the underlying operational and materials aspects, as well as the basic efficacy and biocompatibility of these systems.

Published

2015

20. Antiproliferative Effect of Flavonoids from the Halophyte Vitex Rotundifoliaon Human Cancer Cells

Author

Kim, You Ah, Kim, Hojun, and Seo, Youngwan

Abstract

Three flavonoids, luteolin (1), vitexicarpin (2) and artemetin (3), from the salt marsh plant Vitex rotundifolia, were tested for their anti-proliferative activities in AGS, MCF-7 and HT-29 human cancer cell lines and compared with the control using MTT assay. Among them, 2was most effective with an IC50of 6.9 and 22.8 μM against AGS and HT-29 cells, respectively. In addition, mRNA expression levels of major apoptosis-related genes such as p21, p53, Bcl-2 and Bax in AGS cells were evaluated by reverse-transcription polymerase chain reaction (RT-PCR). Compound 2not only enhanced most remarkably the expression level of tumor suppressor genes p53 and p21, and pro-apoptotic gene Bax at a concentration of 25 μM, but also suppressed the expression level of anti-apoptotic gene Bcl-2 to 20% at the same concentration, thus shifting the Bax/Bcl-2 ratio in favor of apoptosis.

Published

2013