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http://dx.doi.org/10.14400/JDC.2019.17.10.001

Application of Daphnia magna Monitoring System for Real-time Ecotoxicity Assessment  

Lee, Jang-Hoon (Division of Architecture, Civil and Environnmental Engineeting, Hoseo University)
Ko, Woong-Tae (Engineer Department of Convergence Science Technology, Graduate School of Venture, Hoseo University)
Publication Information
Journal of Digital Convergence / v.17, no.10, 2019 , pp. 1-12 More about this Journal
Abstract
In this study, TI(Toxic Index) of Daphnia toximeter corresponded to ecological toxicity standard 1 TU(Toxic Unit) was set up using Daphnia toximeter and when operating NOEC(water quality standards for drinking water) and $EC_{50}$ Daphnia toximeter alarm was issued appropriately, which enables real time ecological toxicity evaluation. I studied to get a good shot and the research was conducted by investigating domestic and international related data and conducting a preliminary study. 6 of 59 hazardous substances (As, Hg, Cr, Diazinon, Dioxane, and Phenol) recommended by the water quality monitoring items for artificial river water were selected and static, dynamic and quality management test, TI was shown to be good in other materials except Diazinon, and as a result of $EC_{50}$ spiking test, TI was matched to TU by distinguishing between 1 TU and 1 TU. in suggesting the complementary point of ecological toxicity management system and the future of research on water Daphnia toximeter.
Keywords
Bio-monitoring; Water flea; Daphnia; Daphnia Toximeter; Ecotoxin management;
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Times Cited By KSCI : 4  (Citation Analysis)
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1 B. G. Anderson. (1944). The toxicity thouresholds of various substances found in industrial wastes as determined by the use of Daphnia magna. Sewage Works Journal, 1156-1165.
2 B. G. Anderson. (1950). The apparent Thresholds of toxicity to Daphnia magna for chlorides of various metals when added to Lake Erie water. Transactions of the American Fisheries Society, 78(1), 96-113. DOI : 10.1577/1548-8659(1948)78[96:tatott]2.0.co;2   DOI
3 A. L. Buikema, D. R. Lee & J. Cairns. (1976). A screening bioassay using Daphnia pulex for refinery wastes discharged into freshwater. Journal of Testing and Evaluation, 4(2), 119-125. DOI : 10.1520/jte10185j   DOI
4 K. E. Biesinger & G. M. Chouristensen. (1972). Effects of various metals on survival, growth, reproduction, and metabolism of Daphnia magna. Journal of the Fisheries Board of Canada, 29(12), 1691-1700. DOI : 10.1139/f72-269   DOI
5 J. C. Yoon et al. (2004). Study on the Application of Daphnia Biomonitering System,
6 S. H. Choe & J. T. Kim. (1996). Early-Warning Monitoring System for Water Resources management. Korean Society for Health Education and Promotion, 217-240
7 S. I. Dodson, S. Ryan, R. Tollrian & W. Lampert. (1997). Individual swimming behavior of Daphnia: effects of food, light and container size in four clones. Journal of Plankton Research, 19(10 ), 1537-1552. DOI : 10.1093/plankt/19.10.1537   DOI
8 C. Buchanan, B. Goldberg & R. McCartney. (19 82). A laboratory method for studying zooplankton swimming behaviors. Hydrobiologia, 94(1), 77-89. DOI : 10.1007/bf00008635   DOI
9 S. Young & C. Getty. (1987). Visually guided fe eding behaviour in the filter feeding cladoceran, Daphaia magna. Animal behaviour, 35(2), 541-548. DOI : 10.1016/s0003-3472(87)80279-8   DOI
10 S. I. Dodson, T. Hanazato & P. R. Gorski. (1995). Behavioral responses of Daphnia pulex exposed to carbaryl and Chaoborus kairomone. Environmental Toxicology and Chemistry, 14(1), 43-50. DOI : 10.1897/1552-8618(1995)14[43:brodpe]2.0.   DOI
11 M. C. Brewer & J. N. Coughlin. (1996). Virtual plankton: a novel approach to the investigation of aquatic predator-prey interactions. Zooplankt on: sensory ecology and physiology, 1, 425-434. DOI : 10.1080/10236249509378931
12 H, D, Shin. (2010). A Study on The Factors in the Survival of Daphnia. Master thesis. Yeung nam University, Gyeongsan.
13 B. J. Lim, S. Y. Park, M. S. Byeon, C. W. Lee, E. S. Lim, H. I. Rhu, S. H. Choi & S. M. Yun. (1995). Studies on th Early Warning Systems with Waterflea, Incheon : Nakdong River Water Resource Inspection Center National Institute of Environmental Reserch.
14 H. J. Lee et al. (2003). Ecotoxicological Studies on the Effect of Heavy Metals Using Daphnia Toximeter. Korean Society on Water Quality. Korean Society on Water Quality, 11, 209-212.
15 J. S. Han. (2016). A Study on the Effective Operation of Biological Monitoring System. Seoul : Waterworks research institute of seoul metropolitan.
16 Y. T. Rim et al. (2001). Behavior Estimation of Water flea on Toxicants. Report of NIER, 23, 639-649.
17 S. G. Lee. (2002). A Study on the Introduction of Integrated Toxicity Management System for Water Quality Hazardous Substances. Daejeon : Korea Institute of Toxicology.
18 S. H. Kim. (2009). Water pollution process test standard(ecological toxicity). Industrial water quality ecological toxicity management conference. (p. 8). Jecheon : Minstry of Environment.
19 National Institute of Environmental Research. (2015). Ecology Toxicity Testing Method and Operation Guidelines. Incheon : National Institute of Environmental Research.
20 G. P. Cheon. (2018. 11. 29). Water Quality Operation is Life Waste... A survey of sewage treatment plants across the country. korea joongang daily, p. 8.
21 D. I. Mount & U. T. Norberg. (1984). A seven day life cycle cladoceran toxicity test. Environmental Toxicology and Chemistry: An International Journal, 3(3), 425-434. DOI : 10.1897/1552-8618(1984)3[425:aslcct]2.0.co;2   DOI
22 J. W. Jeong, M. S. Cha, S. J. Jo & S. J. Lee. (2001). Acute and chouronic toxicity of heavy metals to Daphnia magna. Journal of Environmental Science International, 10(4), 293-298.
23 B. S. Khangarot & P. K. Ray. (1987). Correlation between heavy metal acute toxicity values in Daphnia magna and fish. Bulletin of environmental contamination and toxicology, 38(4), 722-726. DOI : 10.1007/bf01608609   DOI
24 L. Guilhermino, T. C. Diamantino, R. Ribeiro, F. Goncalves & A. M. Soares. (1997). Suitability of Test Media Containing EDTA for the Evaluation of Acute Metal Toxicity to Daphnia magna Straus. Ecotoxicology and environmental safety, 38(3), 292-295. DOI : 10.1006/eesa.1997.1599   DOI
25 M. Corbin. (2009). Problem formulation for the environmental fate and ecological risk, endangered species and drinking water assessments in support of the registered review of chlorpyrifos. Office of Prevention, Pesticides, and Toxic Substances, US EPA.
26 J. K. Lee, Y. K. Lee, Y. S. Yuk, G. Y. Kim. (2017). Convergence Study of Antimicrobial Resistance of Escherichia coli Isolated from Cheonho Reservoir in Cheonan. Journal of the Korea Convergence Society, 8(11), 141-149.   DOI
27 J. Botterweg, C. Van de Guchte & L. W. C. A. Van Breemen. (1989). Bioalarm Systems: a Supplement to traditional monitoring of water quality. H20, 22, 778-794.
28 K. Sanna. (1995). Is Daphnia magna an ecologic ally representative zooplankton species in toxici ty tests? Environ Pollut, 90(2), 263-267. DOI : 10.1016/0269-7491(95)00029-q   DOI
29 Fisher Scientific. (2009). Material Safety Data Sheet. Fair Lawn : Fisher Scientific. https://www.thermofisher.com
30 Y. R. Lee, O. H. Kim, C. H. Kim. (2017). Consideration of Evo-Devo in the Morphogenes is of Fractal Structures in Ammonites. Journal of the Korea Convergence Society, 8(8), 185-190.   DOI
31 B. Y. Choi, S. C. Cho. (2017). Screening of Natural Compounds for Cancer Prevention by Cytotoxicities and AP-1 Reporter Gene Activities. Journal of Convergence for Information Technology, 7(6), 89-95.   DOI
32 T. S. Ki. S. H. Lee. (2017). A Prediction Scheme for Power Apparatus using Artificial Neural Networks. Journal of Convergence for Information Technology, 7(6), 201-207.   DOI