[50] Machine learning-driven microfluidic deglycosylation for ultra-sensitive detection of PD-L1 extracellular vesicles.
Cheng Nie1, Hyorim Jeong1, Sunyoung Park1, Hairi Jiang, Kyung-A Hyun, Jaejeung Kim, Seong Jun Park, Joonchul Shin*, and Hyo-Il Jung*
[49] Extracellular vesicle proteomic analysis improves diagnosis of recurrence in triple-negative breast cancer.
Ju-yong Hyon1, Min Woo Kim1, Kyung-A Hyun1, Yeji Yang, Seongmin Ha, Jee Ye Kim, Young Kim, Sunyoung Park, Hogyeong Gawk, Heaji Lee, Suji Lee, Sol Moon, Eun Hee Han, Jin Young Kim, Ji Yeong Yang, Hyo-Il Jung*, Seung Il Kim*, and Young-Ho Chung*
[48] CD9-enriched extracellular vesicles from chemically reprogrammed basal progenitors of salivary glands mitigate salivary gland fibrosis.
Sunyoung Park1, Yeo-Jun Yoon1, Yongpyo Hong, Jianning Yu, Jae-Min Cho, Ye Jin Jeong, Haeun Yu, Hyorim Jeong, Hyunjin Lee, Seungyeon Hwang, Won-Gun Koh, Ji Yeong Yang, Kyung-A Hyun, Hyo-Il Jung* , and Jae-Yol Lim*
[47] Efficient separation of large particles and giant cancer cells using an isosceles trapezoidal spiral microchannel.
Chanyong Park1, Wanyoung Lim1, Ryungeun Song, Jeonghun Han, Daeun You, Sangmin Kim, Jeong Eon Lee, Danny van Noort, Carl-Fredrik Mandenius, Jinkee Lee, Kyung-A Hyun, Hyo-Il Jung, and Sungsu Park*
[46] High-resolution spiral microfluidic channel integrated electrochemical device for isolation and detection of extracellular vesicles without lipoprotein contamination.
Yong-Hyun Kwon, Sunyoung Park , Hairi Jiang , N.G. Gurudatt , Kyungyeon Lee , Hyorim Jeong , Cheng Nie , Joonchul Shin , Kyung-A Hyun*, and Hyo-Il Jung*
[43] Enhanced enrichment of collected airborne coronavirus and influenza virus samples via a ConA-coated microfluidic chip for PCR detection.
Amin Piri1, Kyung-A Hyun1, Hyo-Il Jung*, Kang Sik Nam, and Jungho Hwang*
[42] Classification of circulating tumor cell clusters by morphological characteristics using convolutional neural network-support vector machine.
Junhyun Park1, SeongMin Ha1, Jaejeung Kim, Jae-Woo Song, Kyung-A Hyun*, Tohru Kamiya*, and Hyo-Il Jung*
[41] Machine learning-powered electrochemical aptasensor for simultaneous monitoring of di(2-ethylhexyl) phthalate and bisphenol A in variable pH environments.
Kyungyeon Lee1, Seong Min Ha1, N.G. Gurudatt, Woong Heo, Kyung-A Hyun, Jayoung Kim, and Hyo-Il Jung*
[39] Continuous Isolation of Stem‐Cell‐Derived Extracellular Vesicles (SC‐EVs) by Recycled Magnetic Beads in Microfuidic Channels.
Haeun Yu, Jaejeung Kim, Jianning Yu, Kyung‐A Hyun, Jae‐Yol Lim, Yeo‐Jun Yoon, Sunyoung Park* and Hyo‐Il Jung*
[38] An all-in-one platform to deplete pathogenic bacteria for rapid and safe enrichment of plant- derived extracellular vesicles.
Zhihao Wen1, Jianning Yu1, Hyorim Jeong, Dong-Uk Kim, Ji Yeong Yang, Kyung-A Hyun, Seoyeon Choi*, Sunyoung Park*, and Hyo-Il Jung*
[37] On-demand delivery of therapeutic extracellular vesicles by encapsulating in monodispersed photodegradable hydrogel microparticles using a droplet microfluidic device.
Jaejeung Kim1, Junhyun Park1, Sujeong Ahn, Sunyoung Park, Haeun Yu, Jianning Yu, Dohyun Kim, Jae-Yol Lim, Kyung-A Hyun*, Won-Gun Koh*, Hyo-Il Jung*
[36] Modularized dynamic cell culture platform for efficient production of extracellular vesicles and sequential analysis.
Seo Yeon Kim1, Seong Min Ha1, Dong-Uk Kim, Junhyun Park, Sunyoung Park, Kyung-A Hyun*, and Hyo-Il Jung*
[35] Electrochemical detection and analysis of tumor-derived extracellular vesicles to evaluate malignancy of pancreatic cystic neoplasm using integrated microfluidic device.
N. G. Gurudatt1, Hogyeong Gwak1, Kyung-A Hyun1, Se-Eun Jeong, Kyungyeon Lee, Sunyoung Park, Moon Jae Chung, Seong-Eun Kim*, Jung Hyun Jo*, and Hyo-Il Jung*
[34] Coil spring-powered pump with inertial microfluidic chip for size-based isolation and enrichment of biological cells.
Hogyeong Gwak, Seong Min Ha, Jae-Woo Song, Kyung-A Hyun, and Hyo-Il Jung*
[33] Ultrasensitive detection and risk assessment of di(2-ethylhexyl) phthalate migrated from daily-use plastic products using a nanostructured electrochemical aptasensor.
Kyungyeon Lee, N G Gurudatt, Woong Heo, Kyung-A Hyun, and Hyo-Il Jung*
[32] A modular microfluidic platform for serial enrichment and harvest of pure extracellular vesicles.
Hogyeong Gwak, Sunyoung Park, Haeun Yu, Kyung-A Hyun*, Hyo-Il Jung*
[31] Electrochemical biosensor for nucleic acid amplification-free and sensitive detection of Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) RNA via CRISPR/Cas13a trans-cleavage reaction.
Woong Heo 1, Kyungyeon Lee 1, Sunyoung Park, Kyung-A Hyun, and Hyo-Il Jung*
[30] Multi-miRNAs panel of tumor-derived extracellular vesicles as promising diagnostic biomarkers of early-stage breast cancer.
Min Woo Kim1, Sunyoung Park1, Hyojung Lee, Hogyeong Gwak, Kyung-A Hyun, Jee Ye Kim, Hyo-Il Jung*, and Seung Il Kim*
[29] Microfluidic recapitulation of circulating tumor cell–neutrophil clusters via double spiral channel-induced deterministic encapsulation.
Junhyun Park, Sunyoung Park, Kyung-A Hyun*, and Hyo-Il Jung*
[28] Microfluidic chip for rapid and selective isolation of tumor-derived extracellular vesicles for early diagnosis and metastatic risk evaluation of breast cancer.
Hogyeong Gwak1, Sunyoung Park1, Junmoo Kim, Jeong Dong Lee, In-Soo Kim, Seung-Il Kim*, Kyung-A Hyun*, Hyo-Il Jung*
[27] Fully Automated System for Rapid Enrichment and Precise Detection of Enterobacteria Using Magneto-Electrochemical Impedance Measurements.
Kirok Kwon, Taehee Yoon, Hogyeong Gwak, Kyungyeon Lee, Kyung-A Hyun, Hyo-Il Jung*
[26] A cost-effective and sensitive photothermal biosensor for the diagnosis of diabetes based on quantifying the sialic acid content on erythrocytes.
Kirok Kwon, Sudesna Chakravarty, Kyung-A Hyun, Nam-Ho Bae, Jaewoo Song, Seok Jae Lee, Hyo-Il Jung*
[25] Detachable microfluidic device implemented with electrochemical aptasensor (DeMEA) for sequential analysis of cancerous exosomes.
Leila Kashefi-Kheyrabadi1, Junmoo Kim1, Sudesna Chakravarty, Sunyoung Park, Hogyeong Gwak, Seung-Il Kim, Mohsen Mohammadniaei, Min-Ho Lee, Kyung-A Hyun*, Hyo-Il Jung*
[24] Automatically controlled microfluidic systems for continuous separation of rare bacteria from blood.
Taehee Yoon, Hui-Sung Moon, Jae-Woo Song, Kyung-A Hyun*, Hyo-Il Jung*
[23] High-throughput microfluidic chip for magnetic enrichment and photothermal DNA extraction of foodborn bacteria.
Kirok Kwon, Hogyeong Gwak, Kyung-A Hyun, Bong-Seop Kwak, Hyo-Il Jung*
[22] On-chip isolation and enrichment of circulating cell-free DNA using microfluidic device.
Hogyeong Gwak, Junmoo Kim, Sunyeong Cha, Yong–Pil Cheon, Seung-Il Kim, Bongseop Kwak, Kyung-A Hyun*, and Hyo-Il Jung*
[21] Highly sensitive and accurate estimation of bloodstain age using smartphone.
Wooseok Choi1, Joonchul Shin1, Kyung-A Hyun, Jae-Woo Song, and Hyo-Il Jung*
[20] Progress in circulating tumor cell research using microfluidic devices.
Hogyeong Gwak, Junmoo Kim, Leila Kashefi-Kheyrabadi, Bongseop Kwak, Kyung-A Hyun*, Hyo-Il Jung*
[19] Salivary Exosome and Cell-Free DNA for Cancer Detection.
Kyung-A Hyun, Hogyeong Gwak, Jaehun Lee, Bongseop Kwak*, Hyo-Il Jung*
[18] A Microfluidic Electrochemical Aptasensor for Enrichment and Detection of Bisphenol A.
Leila Kashefi-Kheyrabadi1, Junmoo Kim1, Hogyeong Gwak, Kyung-A Hyun, Nam Ho Bae, Seok Jae Lee, Hyo-Il Jung*
[17] Continuous adsorption and photothermal lysis of airborne bacteria using a gold nanoparticle-embedded-gemetrically activated surface interaction (gold-GASI) chip.
Kirok Kwon, Kyung-A Hyun, Bong Seop Kwak, Dong Eun Yong, and Hyo-Il Jung *
[16] An integrated microfluidic chip for one-step isolation of circulating tumor cells.
Tae Yoon Lee1, Kyung-A Hyun1, Seung-Il Kim*, and Hyo-Il Jung *
[15] Epithelial-to-mesenchymal transition generates loss of EpCAM and different physical properties in circulating tumor cells from metastatic breast cancer.
Kyung-A Hyun1, Ki-Bang Goo1, Hyunju Han, Joohyuk Sohn, Seung-Il Kim*, Hyo-Il Jung*, and You-Sun Kim*
[14] Isolation and enrichment of circulating biomarkers for cancer screening, detection, and diagnostics.
Kyung-A Hyun, Junmoo Kim, Ho Gyeong Gwak, and Hyo-Il Jung *
[13] Two-stage microfluidic chip for selective isolation of circulating tumor cells(CTCs).
Kyung-A Hyun1, Tae Yoon Lee1, Su Hyun Lee, and Hyo-Il Jung*
[12] Continuous enrichment of circulating tumor cells using a microfluidic lateral flow filtration chip.
Sung-Woo Lee1, Kyung-A Hyun1, Seung-Il Kim, Ji-Yoon Kang*, and Hyo-Il Jung *
[11] Enrichment of circulating tumor cells using a centrifugal affinity plate system.
Sung-Woo Lee1, Kyung-A Hyun1, Seung-Il Kim, Ji-Yoon Kang*, and Hyo-Il Jung *
[10] Photothermal spectral-domain optical coherence reflectometry for direct measurement of hemoglobin concentration of erythorocytes.
Jinyeong Yim, Kun Kim, Suho Ryu, Sungwook Song, Hyun Ok Kim, Kyung-A Hyun, Hyo-Il Jung, and Chulmin Joo*
[9] Label free cell-based assay with spectral-domain optical coherence phase microscopy.
Suho Ryu1, Kyung-A Hyun1, Jung Heo, Hyo-Il Jung and Chulmin Joo *
[8] A High-Q Resonator Using Biocompatible Materials At Microwave Frequencies.
Hee-Jo Lee*, Kyung-A Hyun and Hyo-Il Jung *
[7] Advances and critical concerns with the microfluidic enrichments of circulating tumor cells.
Kyung-A Hyun and Hyo-Il Jung*
[6] Microfluidic sorting of fluorescently activated cells depending on gene expression level.
Haifeng Shang, Kyung-A Hyun, Mi-Hye Kwon, Kwon-Soo Ha, Chulmin Joo* and Hyo-Il Jung*
[5] Negative enrichment of circulating tumor cells using a geometrically activated surface interaction (GASI) chip.
Kyung-A Hyun, Tae Yoon Lee* and Hyo-Il Jung*
[4] Microfluidic devices for the isolation of circulating rare cells : a focus on affinity-based, dielectrophoresis and hydrophoresis.
Kyung-A Hyun and Hyo-Il Jung*
[3] Continual collection and re-separation of circulating tumor cells from blood using multi-stage multi-orifice flow fractionation.
Hui-Sung Moon, Kiho Kwon, Kyung-A Hyun, Tae Seok Sim, Jae Chan Park, Jeong Gun Lee, and Hyo-Il Jung *
[2] Continuous labeling of circulating tumor cells with micro-beads using vortex micromixer for a highly selective isolation.
MingXian Lin, Kyung-A Hyun, Hui-Sung Moon, Tae Seok Sim, Jeong-Gun Lee, Jae Chan Park and Hyo-Il Jung*
[1] Microfluidic flow fractionation device for label-free isolation of circulating tumor cells (CTCs) from breast cancer patients.
Kyung-A Hyun, Kiho Kwon, Hyunju Han, Seung-Il Kim* and Hyo-Il Jung *