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NTIS 바로가기Journal of biophotonics, v.5 no.8/9, 2012년, pp.661 - 672
Schaap, Allison , Rohrlack, Thomas , Bellouard, Yves
AbstractOver the last few decades, lab on a chip technologies have emerged as powerful tools for high‐accuracy diagnosis with minute quantities of liquid and as tools for exploring cell properties in general. In this paper, we present a review of the current status of this technology in the c...
Whitesides, George M.. The origins and the future of microfluidics. Nature, vol.442, no.7101, 368-373.
Psaltis, Demetri, Quake, Stephen R., Yang, Changhuei. Developing optofluidic technology through the fusion of microfluidics and optics. Nature, vol.442, no.7101, 381-386.
El-Ali, Jamil, Sorger, Peter K., Jensen, Klavs F.. Cells on chips. Nature, vol.442, no.7101, 403-411.
Godin, Jessica, Chen, Chun‐Hao, Cho, Sung Hwan, Qiao, Wen, Tsai, Frank, Lo, Yu‐Hwa. Microfluidics and photonics for Bio‐System‐on‐a‐Chip: A review of advancements in technology towards a microfluidic flow cytometry chip. Journal of biophotonics, vol.1, no.5, 355-376.
Abgrall, P, Gué, A-M. Lab-on-chip technologies: making a microfluidic network and coupling it into a complete microsystem—a review. Journal of micromechanics and microengineering.: structures, devices, and systems, vol.17, no.5, R15-R49.
Mark, Daniel, Haeberle, Stefan, Roth, Günter, von Stetten, Felix, Zengerle, Roland. Microfluidic lab-on-a-chip platforms: requirements, characteristics and applications. Chemical Society reviews, vol.39, no.3, 1153-1182.
Gantt, Elisabeth. Phycobilisomes: Light-Harvesting Pigment Complexes. Bioscience, vol.25, no.12, 781-788.
McCormick, Paul V., Cairns Jr, John. Algae as indicators of environmental change. Journal of applied phycology, vol.6, no.5, 509-526.
Brayner, Roberta, Couté, Alain, Livage, Jacques, Perrette, Catherine, Sicard, Clémence. Micro-algal biosensors. Analytical and bioanalytical chemistry, vol.401, no.2, 581-597.
Carmichael, Wayne W.. Health Effects of Toxin-Producing Cyanobacteria: "The CyanoHABs". Human and ecological risk assessment : HERA, vol.7, no.5, 1393-1407.
Chorus, Ingrid, Falconer, Ian R., Salas, Henry J., Bartram, Jamie. HEALTH RISKS CAUSED BY FRESHWATER CYANOBACTERIA IN RECREATIONAL WATERS. Journal of toxicology and environmental health. Part B, Critical reviews, vol.3, no.4, 323-347.
Funari, Enzo, Testai, Emanuela. Human Health Risk Assessment Related to Cyanotoxins Exposure. Critical reviews in toxicology, vol.38, no.2, 97-125.
Anderson, Donald M., Glibert, Patricia M., Burkholder, Joann M.. Harmful algal blooms and eutrophication: Nutrient sources, composition, and consequences. Estuaries, vol.25, no.4, 704-726.
de Figueiredo, D.R., Azeiteiro, U.M., Esteves, S.M., Goncalves, F.J.M., Pereira, M.J.. Microcystin-producing blooms-a serious global public health issue. Ecotoxicology and environmental safety, vol.59, no.2, 151-163.
Sellner, Kevin G., Doucette, Gregory J., Kirkpatrick, Gary J.. Harmful algal blooms: causes, impacts and detection. Journal of industrial microbiology & biotechnology, vol.30, no.7, 383-406.
European Parliament Official J. EU 49 (2006).
Science Carlton J. T. 78 261 1993 10.1126/science.261.5117.78
Culverhouse, PF, Simpson, RG, Ellis, R, Lindley, JA, Williams, R, Parisini, T, Reguera, B, Bravo, I, Zoppoli, R, Earnshaw, G, McCall, H, Smith, G. Automatic classification of field-collected dinoflagellates by artificial neural network. Marine ecology progress series, vol.139, 281-287.
Thiel, Stefan U., Wiltshire, Ron J., Davies, Lance J.. Automated object recognition of blue-green algae for measuring water quality—A preliminary study. Water research, vol.29, no.10, 2398-2404.
Pech-Pacheco, J. L., Alvarez-Borrego, J.. Optical-digital system applied to the identification of five phytoplankton species. Marine biology, vol.132, no.3, 357-365.
Embleton, K. V., Gibson, C. E., Heaney, S. I.. Automated counting of phytoplankton by pattern recognition: a comparison with a manual counting method. Journal of plankton research, vol.25, no.6, 669-681.
Brahma, S. K., Hargraves, P. E., Howard Jr., W. F., Nelson, W. H.. A Resonance Raman Method for the Rapid Detection and Identification of Algae in Water. Applied spectroscopy, vol.37, no.1, 55-58.
Wu, Q., Nelson, W. H., Hargraves, P., Zhang, J., Brown, C. W., Seelenbinder, J. A.. Differentiation of Algae Clones on the Basis of Resonance Raman Spectra Excited by Visible Light. Analytical chemistry, vol.70, no.9, 1782-1787.
Samek, Ota, Jonáš, Alexandr, Pilát, Zdeněk, Zemánek, Pavel, Nedbal, Ladislav, Tříska, Jan, Kotas, Petr, Trtílek, Martin. Raman Microspectroscopy of Individual Algal Cells: Sensing Unsaturation of Storage Lipids in vivo. Sensors, vol.10, no.9, 8635-8651.
Huang, Y.Y., Beal, C.M., Cai, W.W., Ruoff, R.S., Terentjev, E.M.. Micro-Raman spectroscopy of algae: Composition analysis and fluorescence background behavior. Biotechnology and bioengineering, vol.105, no.5, 889-898.
Yentsch, Clarice M., Horan, Paul K., Muirhead, Katharine, Dortch, Quay, Haugen, Elin, Legendre, Louis, Murphy, Lynda S., Perry, Mary Jane, Phinney, David A., Pomponi, Shirley A., Spinrad, Richard W., Wood, Michelle, Yentsch, Charles S., Zahuranec, Bernard J.. Flow cytometry and cell sorting: A technique for analysis and sorting of aquatic particles1. Limnology and oceanography, vol.28, no.6, 1275-1280.
Rutten, Thomas P. A., Sandee, Ben, Hofman, Angelo R. T.. Phytoplankton monitoring by high performance flow cytometry: A successful approach?. Cytometry. the journal of the International Society for Analytical Cytology. Part A, vol.a64, no.1, 16-26.
Boddy, L, Morris, CW, Wilkins, MF, Al-Haddad, L, Tarran, GA, Jonker, RR, Burkill, PH. Identification of 72 phytoplankton species by radial basis function neural network analysis of flow cytometric data. Marine ecology progress series, vol.195, 47-59.
Cunningham, Alexander. A low-cost, portable flow cytometer specifically designed for phytoplankton analysis. Journal of plankton research, vol.12, no.1, 149-160.
Peeters, J. C. H., Dubelaar, G. B. J., Ringelberg, J., Visser, J. W. M.. Optical plankton analyser: A flow cytometer for plankton analysis, I: Design considerations. Cytometry, vol.10, no.5, 522-528.
Dubelaar, George B. J., Groenewegen, Ad C., Stokdijk, Willem, Van Den Engh, G. J., Visser, Jan W. M.. Optical plankton analyser: A flow cytometer for plankton analysis, II: Specifications. Cytometry, vol.10, no.5, 529-539.
Balfoort, H.W., Snoek, J., Smiths, J.R.M., Breedveld, L.W., Hofstraat, J.W., Ringelberg, J.. Automatic identification of algae: neural network analysis of flow cytometric data. Journal of plankton research, vol.14, no.4, 575-589.
Hofstraat, J. W., de Vreeze, M. E. J., van Zeijl, W. J. M., Peperzak, L., Peeters, J. C. H., Balfoort, H. W.. Flow cytometric discrimination of phytoplankton classes by fluorescence emission and excitation properties. Journal of fluorescence, vol.1, no.4, 249-265.
Becker, Annette, Meister, Armin, Wilhelm, Christian. Flow cytometric discrimination of various phycobilin-containing phytoplankton groups in a hypertrophic reservoir. Cytometry, vol.48, no.1, 45-57.
Kutser, Tiit, Metsamaa, Liisa, Strömbeck, Niklas, Vahtmäe, Ele. Monitoring cyanobacterial blooms by satellite remote sensing. Estuarine, coastal and shelf science, vol.67, no.1, 303-312.
Hunter, P.D., Tyler, A.N., Presing, M., Kovacs, A.W., Preston, T.. Spectral discrimination of phytoplankton colour groups: The effect of suspended particulate matter and sensor spectral resolution. Remote sensing of environment, vol.112, no.4, 1527-1544.
Stramski, Dariusz, Bricaud, Annick, Morel, André. Modeling the inherent optical properties of the ocean based on the detailed composition of the planktonic community. Applied optics. Lasers, photonics, and environmental optics, vol.40, no.18, 2929-.
Vardy, Suzanne, Uwins, Phillipa. Fourier Transform Infrared Microspectroscopy as a Tool to Differentiate Nitzschia Closterium and Nitzschia longissima. Applied spectroscopy, vol.56, no.12, 1545-1548.
Kansiz, Mustafa, Heraud, Philip, Wood, Bayden, Burden, Frank, Beardall, John, McNaughton, Don. Fourier Transform Infrared microspectroscopy and chemometrics as a tool for the discrimination of cyanobacterial strains. Phytochemistry, vol.52, no.3, 407-417.
Fluid Imaging Technologies Submersible FlowCAM - In‐Situ Monitoring (http://www.fluidimaging.com/products‐submersible.htm).
Au, Sam H., Shih, Steve C. C., Wheeler, Aaron R.. Integrated microbioreactor for culture and analysis of bacteria, algae and yeast. Biomedical microdevices, vol.13, no.1, 41-50.
Kürsten, Dana, Cao, Jialan, Funfak, Anette, Müller, Philipp, Köhler, J. Michael. Cultivation of Chlorella vulgaris in microfluid segments and microtoxicological determination of their sensitivity against CuCl2 in the nanoliter range. Engineering in life sciences, vol.11, no.6, 580-587.
Cui, Xiquan, Lee, Lap Man, Heng, Xin, Zhong, Weiwei, Sternberg, Paul W., Psaltis, Demetri, Yang, Changhuei. Lensless high-resolution on-chip optofluidic microscopes for Caenorhabditis elegans and cell imaging. Proceedings of the National Academy of Sciences of the United States of America, vol.105, no.31, 10670-10675.
Lutz, B. R., Chen, J., Schwartz, D. T.. Hydrodynamic Tweezers: 1. Noncontact Trapping of Single Cells Using Steady Streaming Microeddies. Analytical chemistry, vol.78, no.15, 5429-5435.
Wu, Chunsheng, Lillehoj, Peter B., Sabet, Leyla, Wang, Ping, Ho, Chih‐Ming. Ultrasonication on a microfluidic chip to lyse single and multiple Pseudo‐nitzschia for marine biotoxin analysis. Biotechnology journal, vol.6, no.2, 150-155.
Tsaloglou, Maria-Nefeli, Bahi, Mahadji M., Waugh, Edward M., Morgan, Hywel, Mowlem, Matthew. On-chip real-time nucleic acid sequence-based amplification for RNA detection and amplification. Analytical methods : advancing methods and applications, vol.3, no.9, 2127-2133.
Zhang, Jinling, Liu, Sixiu, Yang, Pengyuan, Sui, Guodong. Rapid detection of algal toxins by microfluidic immunoassay. Lab on a chip, vol.11, no.20, 3516-3522.
Durrieu, Claude, Tran-Minh, Canh. Optical Algal Biosensor using Alkaline Phosphatase for Determination of Heavy Metals. Ecotoxicology and environmental safety, vol.51, no.3, 206-209.
Chouteau, Celine, Dzyadevych, Sergei, Chovelon, Jean-Marc, Durrieu, Claude. Development of novel conductometric biosensors based on immobilised whole cell Chlorella vulgaris microalgae. Biosensors & bioelectronics, vol.19, no.9, 1089-1096.
Guedri, Houssemeddine, Durrieu, Claude. A self-assembled monolayers based conductometric algal whole cell biosensor for water monitoring. Microchimica acta, vol.163, no.3, 179-184.
Ionescu, Rodica E., Abu-Rabeah, Khalil, Cosnier, Serge, Durrieu, Claude, Chovelon, Jean-Marc, Marks, Robert S.. Amperometric Algal Chlorella vulgaris Cell Biosensors Based on Alginate and Polypyrrole-Alginate Gels. Electroanalysis, vol.18, no.11, 1041-1046.
Chiao, Mu, Lam, Kien B, Lin, Liwei. Micromachined microbial and photosynthetic fuel cells. Journal of micromechanics and microengineering.: structures, devices, and systems, vol.16, no.12, 2547-2553.
Gawad, S., Schild, L., Renaud, Ph.. Micromachined impedance spectroscopy flow cytometer for cell analysis and particle sizing. Lab on a chip, vol.1, no.1, 76-82.
Cheung, Karen, Gawad, Shady, Renaud, Philippe. Impedance spectroscopy flow cytometry: On-chip label-free cell differentiation. Cytometry. the journal of the International Society for Analytical Cytology. Part A, vol.a65, no.2, 124-132.
Sun, T., Green, N.G., Gawad, S., Morgan, H.. Analytical electric field and sensitivity analysis for two microfluidic impedance cytometer designs. IET nanobiotechnology, vol.1, no.5, 69-79.
Benazzi, G., Holmes, D., Sun, T., Mowlem, M.C., Morgan, H.. Discrimination and analysis of phytoplankton using a microfluidic cytometer. IET nanobiotechnology, vol.1, no.6, 94-101.
G.Benazzi Micro Fludic Cytometry for Analysis of Marine Microorganisms PhD Thesis School of Electronics and Computer Science University of Southampton 2010.
French, C. S., Smith, James H. C., Virgin, Hemming I., Airth, Robert L.. Fluorescence-Spectrum Curves of Chlorophylls, Pheophytins, Phycoerythrins, Phycocyanins and Hypericin.. Plant physiology, vol.31, no.5, 369-374.
Oi, V T, Glazer, A N, Stryer, L. Fluorescent phycobiliprotein conjugates for analyses of cells and molecules. The Journal of cell biology, vol.93, no.3, 981-986.
Hashemi, Nastaran, Erickson, Jeffrey S., Golden, Joel P., Ligler, Frances S.. Optofluidic characterization of marine algae using a microflow cytometer. Biomicrofluidics, vol.5, no.3, 032009-.
Hashemi, Nastaran, Erickson, Jeffrey S., Golden, Joel P., Jackson, Kirsten M., Ligler, Frances S.. Microflow Cytometer for optical analysis of phytoplankton. Biosensors & bioelectronics, vol.26, no.11, 4263-4269.
Wu, Jing, Gu, Min. Microfluidic sensing: state of the art fabrication and detection techniques. Journal of biomedical optics, vol.16, no.8, 080901-.
Sugioka, K., Hanada, Y., Midorikawa, K.. Three‐dimensional femtosecond laser micromachining of photosensitive glass for biomicrochips. Laser & photonics reviews, vol.4, no.3, 386-400.
Osellame, R., Hoekstra, H.J.W.M., Cerullo, G., Pollnau, M.. Femtosecond laser microstructuring: an enabling tool for optofluidic lab‐on‐chips. Laser & photonics reviews, vol.5, no.3, 442-463.
Sugioka, Koji, Cheng, Ya. Integrated microchips for biological analysis fabricated by femtosecond laser direct writing. MRS bulletin, vol.36, no.12, 1020-1027.
M.Dugan A. A.Said P.Bado andY.Bellouard The Microflow Cytometer (Pan Stanford Publishing 2010).
Marcinkevičius, Andrius, Juodkazis, Saulius, Watanabe, Mitsuru, Miwa, Masafumi, Matsuo, Shigeki, Misawa, Hiroaki, Nishii, Junji. Femtosecond laser-assisted three-dimensional microfabrication in silica. Optics letters, vol.26, no.5, 277-.
Davis, K. M., Miura, K., Sugimoto, N., Hirao, K.. Writing waveguides in glass with a femtosecond laser. Optics letters, vol.21, no.21, 1729-.
MRS Proc. (Boston) Bellouard Y. 63 782 2003 10.1557/PROC-782-A6.3
Bellouard, Yves, Said, Ali, Dugan, Mark, Bado, Philippe. Fabrication of high-aspect ratio, micro-fluidic channels and tunnels using femtosecond laser pulses and chemical etching. Optics express, vol.12, no.10, 2120-.
Hnatovsky, C., Taylor, R. S., Rajeev, P. P., Simova, E., Bhardwaj, V. R., Rayner, D. M., Corkum, P. B.. Pulse duration dependence of femtosecond-laser-fabricated nanogratings in fused silica. Applied physics letters, vol.87, no.1, 014104-.
Schaap, Allison, Bellouard, Yves, Rohrlack, Thomas. Optofluidic lab-on-a-chip for rapid algae population screening. Biomedical optics express, vol.2, no.3, 658-664.
Schaap, Allison, Rohrlack, Thomas, Bellouard, Yves. Optical classification of algae species with a glass lab-on-a-chip. Lab on a chip, vol.12, no.8, 1527-.
Y.Bellouard A. A.Said M.Dugan andP.Bado Optomechatronic Technologies (ISOT 2009) pp. 445-450 (2009).
Fuhrmann, T., Landwehr, S., El Rharbi-Kucki, M., Sumper, M.. Diatoms as living photonic crystals. Applied physics. B, Lasers and optics, vol.78, no.3, 257-260.
Nanotechnol. Parker A. R. 347 2 2007
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