HOME 연구실소개 응용생체유체역학연구실

응용생체유체역학연구실

Stagnation flow over a plane wall coated with magnetic fluid.  /Schematic of a steam injector.

연구실 소개

본 연구실에서는 건강 및 질병에서 생물학적 흐름의 메커니즘과 생리적 과정과의 상호 관계를 설명하기 위해 유체역학의 기본 원리를 사용하는 생체유체 역학에 대한 다양한 연구를 수행하고 있습니다. 미세유동 채널을 활용한 혈류제어 연구와 더불어 자기공명유속계 (Magnegic Resonance Velocimetry, MRI)를 활용한 혈류 측정법 개선 및 혈류 모델링 연구를 수행하고 있으며 Machine Learning을 활용하는 연구로 응용분야를 확장하고 있습니다.

연구실 담당교수

인적 사항
  • 직위, 성명 : 교수 장일훈
  • 연구실 : 테크노관 320호
  • 전화 : 054-478-7295
  • 이메일 : iroonjang@kumoh.ac.kr
학위 및 경력
  • 2010.02 한양대학교 기계공학부 공학사
  • 2012.02 한양대학교 기계공학과 공학석사
  • 2018.02 한양대학교 융합기계공학과 공학박사
  • 2018.03–2018.09 한양대학교 나노과학기술연구소, 박사후연구원
  • 2018.10–2020.11 Corolado State University, Department of Chemistry, Postdoctoral Researcher
  • 2020.12–2022.11 라디안큐바이오, 책임연구원
  • 2022.12–2023.08 한양대학교 기계공학부, 연구조교수
  • 2023.09 – 현재 금오공과대학교, 조교수
전공분야
  • 유동 분석, 모델링, 유동 가시화, 바이오칩 개발
담당 교과목
  • 응용열유체공학, 유체역학, 컴퓨터원용제도

주요 연구실적

논문
  • H. Dong, C. Im, C. Kang, J.H. Cho, I. Jang (corresponding author), and S. Song, “Investigation of flow behavior in a refrigerator machine room using magnetic resonance velocimetry”, International Journal of Heat and Mass Transfer, 2023, 214, 124446c
  • J. S. Link, C. S. Carrell, I. Jang (co-first author), E. J. O Barstis, Z. D. Call, R. A. Bellows, J. J. O’Donnell-Sloan, J. S. Terry, L. B. R. Anderson, Y. Panraksa, B. J. Geiss, D. S. Dandy, and C. S. Henry, “Capillary flow-driven immunoassay platform for COVID-19 antigen diagnostics”, Analytica Chimica Acta, 2023, 1277, 341634
  • C. Carrell, I. Jang (co-first author), J. Link, J. Terry, M. Scherman, Z. Call, Y. Panraksa, O. Chailapakul, D. S. Dandy, B. J. Geiss, and C. S Henrry, “Capillary driven microfluidic sequential flow device for point-of-need ELISA: COVID-19 serology testing”, Analytical Methods, 2023, 15, 2721-2728
  • Y. Panraksa, I. Jang (co-first author), C. S. Carrell, A. G. Amin, O. Chailapakul, D. Chatterjee, and C. S. Henry+, “Simple manipulation of enzyme-linked immunosorbent assay (ELISA) using an automated microfluidic interface”, Analytical Methods, 2022, 14, 1774
  • Z. D. Call, I. Jang, B. J. Geiss, D. S. Dandy, and C. S. Henry+, “Progress toward a Simplified UTI Diagnostic: Pump-Free Magnetophoresis for E. coli Detection”, Analytical Chemistry, 2022, 94, 7545-7550
  • I. C. Samper, A. Sanchez-Cano, W. Khamcharoen, I. Jang, W. Siangproh, E. Baldrich, B. J. Geiss, D. S. Dandy, and C. S. Henry+, “Electrochemical Capillary-Flow Immunoassay for Detecting Anti-SARS-CoV‑2 Nucleocapsid Protein Antibodies at the Point of Care”, ACS Sensors, 2021, 6, 4067-4075
  • T. Sierra, I. Jang, E. Noviana, A. G. Crevillen, A. Escarpa, and C. S. Henry+, “Pump-free microfluidic device for the electrochemical detection of a1-Acid glycoprotein”, ACS Sensors, 2021, 6, 8, 2998-3005
  • E. Noviana, O. Tugba, C. S. Carrell, J. S. Link, C. McMahon, I. Jang, and C. S. Henry+, “Microfluidic paper-based analytical devices: From design to applications”, Chemical Reviews, 2021, 121, 19, 11835-11885
  • I. Jang, H. Kang, S. Song, D. S. Dandy, B. J. Geiss, and C. S. Henry+, “Flow control in a laminate capillary-driven microfluidic device”, Analyst, 2021, 146, 1932-1939
  • S. Boonkaew, I. Jang, E. Noviana, W. Siangproh, O. Chailapakul+, and C. S. Henry+, “Electrochemical paper-based analytical device for multiplexed, point-of-care detection of cardiovascular disease biomarkers”, Sensors and Actuators B, 2020, 330, 129336
  • Z. D. Call, C. S. Carrell, I. Jang, B. J. Geiss, D. S. Dandy, and C. S. Henry+, “Paper-based pump-free magnetophoresis”, Analytical Methods, 2020, 12, 5177-5185
  • I. Jang, D. B. Carrao, R. F. Menger, A. R. M. de Oliveira, and C. S. Henry+, “Pump-free microfluidic rapid mixer for analysis of organophosphate pesticide”, ACS Sensors, 2020, 5, 7, 2230-2238
  • I. Jang, K. E. Berg, and C. S. Henry+, “Viscosity measurements utilizing a fast-flow microfluidic paper-based device”, Sensors and Actuators B, 2020, 15, 128240
  • E. Noviana, C. P. McCord, K. M. Clark, I. Jang, and C. S. Henry+, “Electrochemical paper-based devices: sensing approaches and progress toward practical applications”. Lab on a Chip, 2020, 20, 9-34, (Critical review, Front cover)
  • H. Kang, I. Jang+, S. Song+, and S. C. Bae, “Development of a paper-based viscometer for blood plasma using colorimetric analysis”. Analytical Chemistry, 2019, 91, 7, 4868-4875
  • I. Jang, G. Kim, and S. Song+, “Mathematical model for mixing in a paper-based channel and applications to the generation of a concentration gradient”, International journal of Heat and Mass Transfer, 2018, 120, 830-837
  • I. Jang and S. Song+, “Facile and precise flow control for a paper-based microfluidic device through varying paper permeability”, Lab on a Chip, 2015, 15, 3405-3412
  • I. Jang and S. Song+, “A model for prediction of minimum coating thickness in high speed slot coating”, International Journal of Heat and Fluid Flow, 2013, 40, 180-185
특허
  • “Electrochemical microfluidic assay devices”, Charles S. Henry, Brian J. GEISS, David S. DANDY, Isabelle SAMPER, Ana SANCHEZ-CANO, Ilhoon Jang, WO2022036346A1
  • “Capillary-driven colorimetric assay devices”, Charles S. Henry, Brian J. Geiss, David S. Dandy, Cody Carrell, Jeremy Link, Isabelle SAMPER, Ana SANCHEZ-CANO, Ilhoon Jang, Zachary CALL, WO2022027060A1
  • “Flow control in microfluidic devices”, Charles S. Henry, Ilhoon Jang, WO2022040690A1
  • “소수도 가변재질기반 미세유동채널 및 그 제작방법”, 송시몬, 장일훈, 김강준, 10-1508317
  • “다공성 물질용 밸브”, 송시몬, 김지태, 김강준, 장일훈, 10-1530935
  • “검사 스트립”, 송시몬, 장일훈, 김회율, 10-2009116
  • “점도측정계, 점도측정계 사용 방법 및 점도측정 프로그램”, 송시몬, 장일훈, 강현웅, 10-2274177