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KCIEfficient separation and enrichment of pathogenic bacteria from complex matrices are crucial for the detection and downstream biomedical investigations. Herein, we report a floating magnetic membrane comprised of superparamagnetic nanoparticles and ca...
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RISS 인기검색어
https://www.riss.kr/link?id=A107316358
- 저자
- 발행기관
- 학술지명
- 권호사항
-
발행연도
2021
-
작성언어
English
- 주제어
-
등재정보
KCI등재,SCOPUS,SCIE
-
자료형태
학술저널
-
수록면
61-68(8쪽)
-
KCI 피인용횟수
0
- DOI식별코드
- 제공처
-
0
상세조회 -
0
다운로드
부가정보
다국어 초록 (Multilingual Abstract)
Efficient separation and enrichment of pathogenic bacteria from complex matrices are crucial for the detection and downstream biomedical investigations. Herein, we report a floating magnetic membrane comprised of superparamagnetic nanoparticles and cationic polymer chains for rapid capture and enrichment of pathogenic bacteria under continuous flow. Magnetic nanoparticles combined with polymeric chains have shown affordable features to capture, release, and concentrate the pathogens by applying an external magnetic field. We have verified the modulated porous characteristics of the floating magnetic membrane depending on the molecular weight of cationic polymer chains and demonstrated rapid enrichment of pathogenic bacteria from aqueous fluid in the capillary glass tube (> 50-fold). Structural flexibility of the magnetic membrane allows the liquid and smaller species to pass through but efficiently induces binding of the bacteria on the antibodyfunctionalized magnetic nanoparticles of the floating virtual web. The magnetic membrane enables size-selective filtration and target-specific trapping through ionic exchange and immunomagnetic isolation. This study implies that spatiotemporal application of the magnetic membrane for rapid enrichment of biological targets in a large volume of continuous flow using microfluidic devices and biochips.
Efficient separation and enrichment of pathogenic bacteria from complex matrices are crucial for the detection and downstream biomedical investigations. Herein, we report a floating magnetic membrane comprised of superparamagnetic nanoparticles and cationic polymer chains for rapid capture and enrichment of pathogenic bacteria under continuous flow. Magnetic nanoparticles combined with polymeric chains have shown affordable features to capture, release, and concentrate the pathogens by applying an external magnetic field. We have verified the modulated porous characteristics of the floating magnetic membrane depending on the molecular weight of cationic polymer chains and demonstrated rapid enrichment of pathogenic bacteria from aqueous fluid in the capillary glass tube (> 50-fold). Structural flexibility of the magnetic membrane allows the liquid and smaller species to pass through but efficiently induces binding of the bacteria on the antibodyfunctionalized magnetic nanoparticles of the floating virtual web. The magnetic membrane enables size-selective filtration and target-specific trapping through ionic exchange and immunomagnetic isolation. This study implies that spatiotemporal application of the magnetic membrane for rapid enrichment of biological targets in a large volume of continuous flow using microfluidic devices and biochips.
참고문헌 (Reference)
1 Lee, W., "Ultrarapid detection of pathogenic bacteria using a 3D immunomagnetic fow assay" 86 : 6683-6688, 2014
2 Armbrecht, L., "Self-assembled magnetic bead chains for sensitivity enhancement of microfuidic electrochemical biosensor platforms" 15 : 4314-4321, 2015
3 Zhu, C. L., "Rapid, simple, and high-throughput antimicrobial susceptibility testing and antibiotics screening" 50 : 9607-9610, 2011
4 Dao, T.N.T., "Rapid and sensitive detection of Salmonella based on microfuidic enrichment with a label-free nanobiosensing platform" 262 : 588-594, 2018
5 Hobson, N. S., "Microbial detection" 11 : 455-477, 1996
6 Kang, J. H., "Magnetophoretic continuous purifcation of single-walled carbon nanotubes from catalytic impurities in a microfuidic device" 3 : 1784-1791, 2007
7 Kwon, D., "Magnetophoretic chromatography for the detection of pathogenic bacteria with the naked eye" 85 : 7594-7598, 2013
8 Liong, M., "Magnetic barcode assay for genetic detection of pathogens" 4 : 1752-, 2013
9 Oh, S., "Magnetic activated cell sorting (MACS) pipette tip for immunomagnetic bacteria separation" 272 : 324-330, 2018
10 Rida, A., "Long-range transport of magnetic microbeads using simple planar coils placed in a uniform magnetostatic feld" 83 : 2396-2398, 2003
1 Lee, W., "Ultrarapid detection of pathogenic bacteria using a 3D immunomagnetic fow assay" 86 : 6683-6688, 2014
2 Armbrecht, L., "Self-assembled magnetic bead chains for sensitivity enhancement of microfuidic electrochemical biosensor platforms" 15 : 4314-4321, 2015
3 Zhu, C. L., "Rapid, simple, and high-throughput antimicrobial susceptibility testing and antibiotics screening" 50 : 9607-9610, 2011
4 Dao, T.N.T., "Rapid and sensitive detection of Salmonella based on microfuidic enrichment with a label-free nanobiosensing platform" 262 : 588-594, 2018
5 Hobson, N. S., "Microbial detection" 11 : 455-477, 1996
6 Kang, J. H., "Magnetophoretic continuous purifcation of single-walled carbon nanotubes from catalytic impurities in a microfuidic device" 3 : 1784-1791, 2007
7 Kwon, D., "Magnetophoretic chromatography for the detection of pathogenic bacteria with the naked eye" 85 : 7594-7598, 2013
8 Liong, M., "Magnetic barcode assay for genetic detection of pathogens" 4 : 1752-, 2013
9 Oh, S., "Magnetic activated cell sorting (MACS) pipette tip for immunomagnetic bacteria separation" 272 : 324-330, 2018
10 Rida, A., "Long-range transport of magnetic microbeads using simple planar coils placed in a uniform magnetostatic feld" 83 : 2396-2398, 2003
11 Lee, H., "Lenz’s law-based virtual net for detection of pathogenic bacteria from water" 91 : 15585-15590, 2019
12 Joo, J., "Highly sensitive diagnostic assay for the detection of protein biomarkers using microresonators and multifunctional nanoparticles" 6 : 4375-4381, 2012
13 Jones, K.E., "Global trends in emerging infectious diseases" 451 : 990-994, 2008
14 Inglis, D. W., "Continuous microfuidic immunomagnetic cell separation" 85 : 5093-5095, 2004
15 Han, K. H., "Continuous magnetophoretic separation of blood cells in microdevice format" 96 : 5797-5802, 2004
16 Carrillo-Carrion, C., "Colistinfunctionalised CdSe/ZnS quantum dots as fuorescent probe for the rapid detection of Escherichia coli" 26 : 4368-4374, 2011
17 Pankhurst, Q. A., "Applications of magnetic nanoparticles in biomedicine" 36 : R167-R181, 2003
18 Xue, L., "An ultrasensitive fuorescent biosensor using high gradient magnetic separation and quantum dots for fast detection of foodborne pathogenic bacteria. Sens" 265 : 318-325, 2018
19 Luan, Y., "An enhanced recyclable 3D adsorbent for diverse bio-applications using biocompatible magnetic nanomulberry and cucurbituril composites" 10 : 443-, 2020
20 Joo, J., "A facile and sensitive method for detecting pathogenic bacteria using personal glucose meters" 188 : 1250-1254, 2013
21 Chun, C., "A facile and sensitive immunoassay for the detection of alpha-fetoprotein using gold-coated magnetic nanoparticle clusters and dynamic light scattering" 47 : 11047-11049, 2011
22 Joo, J., "A facile and sensitive detection of pathogenic bacteria using magnetic nanoparticles and optical nanocrystal probes" 137 : 3609-3612, 2012
23 김희정, "A Rapid Method for Estimation of Cariogenic Bacteria Based on a Stationary Liquid Phase Lab-on-a-chip" 한국바이오칩학회 12 (12): 52-58, 2018
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분석정보
인용정보 인용지수 설명보기
학술지 이력
| 연월일 | 이력구분 | 이력상세 | 등재구분 |
|---|---|---|---|
| 학술지등록 | 한글명 : BioChip Journal외국어명 : BioChip Journal | ||
| 2023 | 평가예정 | 해외DB학술지평가 신청대상 (해외등재 학술지 평가) | |
| 2020-01-01 | 평가 | 등재학술지 유지 (해외등재 학술지 평가) |  |
| 2013-10-01 | 평가 | 등재학술지 선정 (기타) | |
| 2011-01-01 | 평가 | 등재후보 1차 PASS (등재후보1차) |  |
| 2009-01-01 | 평가 | SCIE 등재 (신규평가) | |
학술지 인용정보
| 기준연도 | WOS-KCI 통합IF(2년) | KCIF(2년) | KCIF(3년) |
|---|---|---|---|
| 2016 | 1.33 | 0.25 | 0.88 |
| KCIF(4년) | KCIF(5년) | 중심성지수(3년) | 즉시성지수 |
| 0.66 | 0.53 | 0.255 | 0.1 |
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