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1
Academic Journal
Purification of landscape water by using an innovative application of subsurface flow constructed wetland

Authors: Chyan, Jih Ming, Lu, Chien Chang, Shiu, Ruei Feng, Bellotindos, Luzvisminda M.

Contributors: Chia Nan Univ Pharm & Sci, Dept Environm Resources Management, Chia Nan Univ Pharm & Sci, Dept Environm Sci & Engn, Natl Sun Yat Sen Univ, Dept Marine Environm & Engn, Univ Zamboanga, Archie Eustaquio Res Lab7000

Subject Terms: Embedded subsurface flowconstructed wetlands, Biochemical oxygen demand, Ammonium-nitrogen, Total phosphorus, Suspended solids, Chlorophyll-a, efficiency

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Relation: Environmental Science and Pollution Research, v.23 n.1, pp.535-545; https://ir.cnu.edu.tw/handle/310902800/30994; https://ir.cnu.edu.tw/bitstream/310902800/30994/1/index.html

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14
Dissertation/ Thesis
薄膜接觸技術處理氨氮廢水之研究 ; Study on removing aqueous ammonia by membrane contactor process

Authors: 侯守威

Contributors: 嘉南藥理科技大學:環境工程與科學系暨研究所, 賴振立

Subject Terms: 薄膜接觸, 氨氮去除, 聚偏氟乙烯, 聚四氟乙烯, membrane contactor, ammonium removal, PTFE, polyvinylidene fluoride (PVDF)

Relation: 校內外均一年後公開,學年度:99,105頁; 1. Xiaoyao Tan, S.P. Tan, W.K. Teo, K. Li, Polyvinylidene fluoride (PVDF) hollow fibre membranes for ammonia removal from water, Journal of Membrane Science, Volume 271, March 2006, Pages 59-68. 2. Kohji Yamamoto, Minoru Fukushima, Kunio Oda, Effects of stirring on residual chlorine during chlorination of seawater containing ammonia nitrogen, Water Research, Volume 24, May 1990, Pages 649-652. 3. Vit Mateju, Simona Cizinska, Jakub Krejci, Tomas Janoch, Biological water denitrification-A review, Enzyme and Microbial Technology, Volume 14, March 1992, Pages 170-183. 4. Yi Wang, Yuichi Kmiya, Toshio Okuhara, Removal of low-concentration ammonia in water by ion-exchange using Na-mordenite, Water Research, Volume 41, January 2007, Pages 269-276. 5. P. Ciambelli, P. Corbo, C. Porcelli, A. Rimoli, Ammonia removal from wastewater by natural zeolites, Zeolites, Volume 5, May 1985, Pages 184-187. 6. 蔣本基,工業廢水逆滲透理論,經濟部工業局,(1996) 7. 鄭領英,王學松,膜的高科技應用,五南圖書出版公司,台北(2003) 8. 莊清榮,游勝傑,流體中的最佳守門員-微過濾與超過濾,科學發展,(2008) 9. 童國倫,阮若屈,最小心眼的薄膜-逆滲透膜與奈米濾膜,科學發展,(2008) 10. S. B. Sadr Ghayeni, P. J. Beatson, R. P. Schneider, A. G. Fane, Adhesion of waste water bacteria to reverse osmosis membranes, Journal of Membrane Science, Volume 138, 7 January 1998, Pages 29-42. 11. M. Mulder,膜技術基本原理,清華大學出版社,(1999) 12. Rob Klaassen, Paul Feron, Albert Jansen, Membrane contactor applications, Desalination, Volume 224, April 2008, Pages 81-87. 13. V.Y. Dindore, D.W.F. Brilman, G.F. Versteeg, Hollow fiber membrane contactor as a gas–liquid model contactor, Chemical Engineering Science, Volume 60, January 2005, Pages 467-479. 14. A. Mansourizadeh, A.F. Ismail, CO2 stripping from water through porous PVDF hollow fiber membrane contactor, Desalination, Volume 273, June 2011, Pages 386-390. 15. K. Soldenhoff, M. Shamieh, A. Manis, Liquid-liquid extraction of cobalt with hollow fiber contactor, Journal of Membrane Science, Volume 252, April 2005, Pages 183-194. 16. Mahdi Hedayat, Mohammad Soltanieh, Seyyed Abbas Mousavi, Simultaneous separation of H2S and CO2 from natural gas by hollow fiber membrane contactor using mixture of alkanolamines, Journal of Membrane Science, Volume 377, July 2011, Pages 191-197. 17. P. Keshavarz, J. Fathikalajahi, S. Ayatollahi, Mathematical modeling of the simultaneous absorption of carbon dioxide and hydrogen sulfide in a hollow fiber membrane contactor, Separation and Purification Technology, Volume 63, October 2008, Pages 145-155. 18. 謝濬帆碩士論文,利用中空纖維薄膜接觸器結合醇胺水溶液吸收二氧化碳之研究,中原大學,(2008) 19. 陳偉杰碩士論文,電漿改質聚丙烯中空纖維膜接觸器於二氧化碳吸收應用之研究,中原大學,(2008) 20. Jiahui Shao, Huifeng Liu, Yiliang He, Boiler feed water deoxygenation using hollow fiber membrane contactor, Desalination, Volume 234, December 2008, Pages 370-377. 21. Isabelle Souchon, Violaine Athès, François-Xavier Pierre, Michèle Marin, Liquid-liquid extraction and air stripping in membrane contactor: application to aroma compounds recovery, Desalination, Volume 163, March 2004, Pages 39-46. 22. V. Y. Dindore, D. W. F. Brilman, P. H. M. Feron, G. F. Versteeg, CO2 absorption at elevated pressures using a hollow fiber membrane contactor, Journal of Membrane Science, Volume 235, June 2004, Pages 99-109. 23. Qian Yang, N.M. Kocherginsky, Copper removal from ammoniacal wastewater through a hollow fiber supported liquid membrane system Modeling and experimental verification, Journal of Membrane Science, Volume 297, July 2007, Pages 121-129. 24. 林素霞博士論文,以中空纖維薄膜接觸器同時萃取金屬陰陽離子之效率與質傳分析,元智大學,(2002) 25. 彭志剛碩士論文,以電漿處理聚四氟乙烯表面改質之研究,中央大學,(2001) 26. 沈坤昇碩士論文,PTFE-Nafion複合膜的製作及性能研究,元智大學,(2003) 27. 王志偉碩士論文,鐵氟龍表面電漿處理與分析,清華大學,(2006) 28. Ken-ichi Kurumada, Taketo Kitamura, Naohiro Fukumoto, Masahiro Oshima, Masataka Tanigaki, Shin-ichi Kanazawa, Structure generation in PTFE porous membranes induced by the uniaxial and biaxial stretching operations , Journal of Membrane Science, Volume 149, October 1998, Pages 51-57. 29. I. Toshiaki, N. Norikane, M. Takuya, Process of making a porous PTFE membrane, US Patent 5910277, 8 Junuary 1999. 30. 李維倫碩士論文,含浸磺酸化聚苯乙烯之聚四氟乙烯膜於燃料電池質子交換膜之應用,元智大學,(2001) 31. 陳秋萍碩士論文,聚乙烯共乙烯醇-聚偏二氟乙烯複合膜於滲透蒸發與蒸氣滲透之探討,中原大學,(2005) 32. Nana Li, Changfa Xiao, Shulin An, Xiaoyu Hu, Preparation and properties of PVDF/PVA hollow fiber membranes, Desalination, Volume 250, January 2010, Pages 530-537. 33. Fu Liu, N. Awanis Hashim, Yutie Liu, M.R. Moghareh Abed, K. Li, Progress in the production and modification of PVDF membranes, Journal of Membrane Science, Volume 375, June 2011, Pages 1-27. 34. 黃郁馨碩士論文,奈米多孔型聚偏二氟乙烯薄膜之製備與研究,淡江大學,(2004) 35. Amish Mandowara, Prashant K. Bhattacharya, Simulation studies of ammonia removal from water in a membrane contactor under liquid-liquid extraction mode, Journal of Environmental Management, Volume 92, January 2011, Pages 121-130. 36. M. Sarioglu , Removal of ammonium from municipal wastewater using natural Turkish (Dogantepe) zeolite , Separation and Purification Technology, Volume 41, January 2005, Pages 1-11. 37. 陳國誠,廢水生物處理學,國立編譯館主編,(1991); https://ir.cnu.edu.tw/handle/310902800/24560; https://ir.cnu.edu.tw/bitstream/310902800/24560/-1/etd-0719111-011353.pdf; https://ir.cnu.edu.tw/bitstream/310902800/24560/-1/index.html

Availability: https://ir.cnu.edu.tw/handle/310902800/24560
https://ir.cnu.edu.tw/bitstream/310902800/24560/-1/etd-0719111-011353.pdf
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15
Dissertation/ Thesis
以元素鐵為主之新穎系統處理受硝酸鹽污染地下水之操作分析 ; Operation analysis of innovative Fe0-based system for nitrate-contaminated groundwater treatment.

Authors: 李俊儀

Contributors: 廖志祥, 嘉南藥理科技大學:環境工程與科學系曁研究所

Subject Terms: 空氣曝氣法, 空氣打氣機, 銨離子(NH4+), Micro size of zero valent iron(Fe0), Ferrous iron (Fe2+), Ammonium iron(NH4+), Air stripping, Air pump, Sodium hydroxide (NaOH), Iron oxide coated quartz sand

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Relation: 校內外完全公開 ,學年度:97,140 頁; 參考文獻 Agrawal, A. and Tratnyek, P.G. (1996). Reduction of nitro aromatic compounds by zero-valent iron metal .Environmental Science and Technology 36,299-306. Alowitz, M.J. and Scherer, M.M. (2002). Kinetics of nitrate, nitrite, and Cr(VI) reduction by iron metal. Environmental Science and Technology 36,299-306. Banens , R.J. and Devis, J.R. (1998). Comprehensive approaches to eutrophication management: the Australian example. Water Science and Technology 37:217-225. Benjamin M.M. (2002). Water chemistry (1sted.). New York: McGraw-Hill. Bonmati, A. and Flotats, X. (2003). Air stripping of ammonia from pig slurry: characterization and feasibility as a pre- or post-treatment to mesophilic anaerobic digestion. Waste Management 23:261-272. Cao, J., Wei, L., Huang, Q., Wang, L. and Han, S. (1999). Reducing degradation of azo dye by zero-valent iron in aqueous solution. Chemosphere 38(3): 565-571. Chalermchai Ruangchainikom,Chih-Hsiang Liao,Jin Anotai,Ming-Tang Lee. Effects of water characteristics on nitrate reduction by the Fe0/CO2 process, Chemosphere 2005. In press. Chalermchai Ruangchainikom , Chih-Hsiang Liao , Jin Anotai , Ming-Tang Lee. Characteristics of nitrate reduction by zero-valent iron power in the recirculated and CO2-bubbled system, Water Research 40 (2006) 195-204. Chang, H.L., Hwang, R.J., Gung, H.B., Horng, S.J. and Su, J.L. (2002). Heterotrophic-denitrification pilot study in Hsin-Chia Water Treatment Plant on Nan-Tou operation station. Proceedings. The 8th International Conference on Drinking Water Management and Treatment Technologies. May 27-29, Chung Shan University, Kaohsiung, Taiwan: 3-14-3-30. Chen, H. Y., Yeh, H. H., Tsai, M. C. and Lai, W. L. (2000). The application of fluidized bed crystallization in drinking water softening. Journal of the Chinese Institute of Environmental Engineering. 10:177-184. Chen, Y. M., Li, C. W. and Chen, S. S. (2005). Fluidized zero valent iron bed reactor for nitrate removal. Chemophere 59:753-759. Chew, C. F. and Zhang, T. C. (1998). In situ remediation of nitrate contaminated groundwater by electrokinetics/iron wall processes. Water Science and Technology 36: 135-142. Choe, S., Chang, Y. Y., Hwang, K. Y. and Khim, J. (2000). Kinetics of reductive denitrification by nanoscale zero-valent iron. Chemosphere 41: 1307-1311. Choe, S., Liljestrand, H. M. and Khim, J. (2004). Nitrate reduction by zero-valent iron under different pH regimes. Applied Geochemistry 19: 335-342. Chuang, F. W., Larson, R. A., Wessman, M. S. (1995). Zero-valent iron promoted dechlorination of polychlorinated biphynyls. Environmental Science and Technology. 29: 2460-2463. Cheung, K. C., Chu, L. M. and Wong, M. H. (1997). Ammonia stripping as a pretreatment for landfill leachate. Water, Air, and Soil Pollution. 94, 209-221. C. Ruangchainikom, C.H. Liao, J. Anotai and M.T. Lee. Innovative process using Fe0/CO2 For the removal of nitrate from groundwater , Water Science and Technology:Water Supply Vol 5 No 5 pp 49-56. Flis, J. (1991). Stress corrosion cracking of structural steels in nitrate solutions. In:Flis, J. (Ed.), Corrosion of Metals and Hydrogen-Related Phenomena. Materials Science Monograph, Vol. 59. Elsevier, Amsterdam, NL, pp.57-94. Furukawa, Y., Kim, J. W., Watkins, J. and Wilkin, R.T. (2002). Formation of ferrihydrite and associated iron corrosion production in permeable reactive barriers of zero-valent iron corrosion production in permeable reactive barriers of zero-valent iron. Environmental Science and Technology. 36:5469-5475. Gillham, R. W. and O’Hammesin, S. F. (1994). Enhanced degradstion of halogenated aliphatics by zero-valent iron. Ground Water 32(6): 958-967. Gonzalez Benito, G. and Garcia Cubero, M. T. (1996). Ammonia elimination from beet sugar factory condensate streams by a stripping absorption system. Zuckerindustrie 121:721-726. Gotpagar, J., Grulke, E., Tsang, T. and Bhattacharvva, D. (1997). Reductive dehalogenation of trichloroethylene using zero-valent iron. Environmental Progress. 16(2):137-142. Hsu, C. Y., Liao, C. H. and Lu, M. C. (2004). Treatment of aqueous nitrate by zero valent iron powder in the presence of CO2 bubbling. Groundwater Monitoring and Remediation 24(4): 82-87. Hu, H. Y., Goto, N., Fujie, K., Kasakusa, T. and Tsubone, T. (2001). Reductive treatment characteristics of nitrate by metallic iron in aquatic solution. Journal of Chemical Engineering of Japan 34:1097-1102. Huang, C. P., Wang, H. W. and Chiu, P. C. (1998) Nitrate reduction by metallic iron. Water Research 32:2257-2264. Huang, Y. H. and Zheng, T. C. (2002). Kinetics of nitrate reduction by iron at near neutral pH. Journal of Environmental Engineering 128: 604-611. Huang, Y. H. and Zheng, T. C. (2004). Effects of low pH on nitrate reduction by iron powder. Water Research 38: 2631-2642. Kelly, E. J. (1965). The active iron electrode :iron dissolution and hydrogen evolution reactions in acidic sulfate solutions. Journal of Electrochemistry Society. 112(2): 679-687. Janus, H. M. and Van Der Roest, H. F. (1997). Don’t reject the idea of treating reject water. Water Science and Technology 35(10):27-34. Kabdasli, I., Tunay, O., Ozturk, I., Yilmaz, S. and Arikan, O. (2000). Ammonia removal from young landfill leachate by magnesium ammonium phosphate precipitation and air stripping. Water Science and Technology 41(1),237-240. Karen M. M. (1987). Nitrate in drinking water. Available online at [http://ohioline.osu.edu/b744/b744_5.html]. Kielemoes, J., De Boever, P. and Verstraete, W. (2000). Influence of denitrification on the corrosion of iron and stainless steel powder. Environmental Science and Technology 34;663-671. Kim, Y. H. and Carraway, E. R. (2000). Dechlorination of pentachlorophenol by zero valent iron and modified zero valent iron. Environmental Science and Technology 34:2014-2017. Liao, P. H., Chen, A. and Lo, K. V. (1995). Removal of nitrogen from swine manure wastewaters by ammonia stripping. Bioresource Technology 54:17-20. Liao, C. H., Kang, S. F. and Hsu, Y. W. (2003). Characteristics of reductive removal of nitrate by suspended zero-valent iron powder. Journal of the Chinese Institute of Environmental Engineering 13(4): 251-261. Liao, C. H., Kang, S. F. and Hsu, Y. W. (2003). Zero-valent iron reduction of nitrate in the presence of ultraviolent light, organic matter and hydrogen peroxide. Water Research 37: 4109- 4118. Lide, D. (1993). Handbook of Chemistry and Physics. A Ready-reference Book of Chemical and Physical Data. CRC Press, Boca Raton. Menzer, R.E. (1991). Water and soil pollutants. In: AMDUR, M.O.; DOULL, J.;KLAASEN, C.D. Toxicology: the basic science of poisons. New York: Casarett & Doull’s: pp. 872-902. Monicha, V. K. and Prabhakar, A. V. S. (1998). Ammonia removal and recovery from urea fertilizer plant waste. Environmental Technology Letters 9: 655-664. Orth, W. S. and Grillham,R. W. (1996). Dechlorination of trichloroethene in aqueos solution using Fe0. Environmental Science and Technology 30: 66-71. Piromlert, S. (1995). Nitrate affected groundwater in northeast Thailand. Proceedings, International Conference on Geology and Mineral Resources of Indochina (Geo-Indo’95): 523 -520. Sayles, G. D. You, G., Wang, M. and Kupferle, M. (1997). DDT, DDD, and DDE dechlorination by zero-valent iron. Environmental Science and Technology 31: 3448-3454. Siantar, D. P., Schreier, C. G., Chou, C. S. and Reinhard, M. (1996). Treatment of 1,2-dibromo-3-chloropropane and nitrate contaminated water with zero-valent iron or hydrogen/palladium catalysts. Water Research 30: 2315-2322. Schiweck, H. and Nahle, C. (1990). Removal of ammonia from condensates and surplus condenser water by stripping with air. Zuckerindustrie 115: 639-647. Thorndahl, U. (1992). Nitrogen removal by treatment of reject water. In: Proceeding of European Conference on Nutrient Removal from Wastewater , Leeds: pp. 1-15. Till, B. A., Weathers, L. J. and Alvarez, P. J. J. (1998). Fe0 supported autotrophic denitrification. Environmental Science and Technology 32:634-639. U. S. EPA. (2000). Wastewater Technology Fact Sheet Ammonia stripping EPA 832-F-00-019, Washington D. C. Van Der Veen, C. and Graveland, A. (1988). Central softening by crystallization in a fluidized-bed process . Journal AWWA: 51-56. Watergroup (1990). Purification reject water from sewage treatment plants. Results of Test Run with Pilot Plant at the Saltebakkens Sewage Treatment Plant ,Frederikshavn, Denmark. Watergroup Technical Letter: pp. 1-9. Walton, G. (1951). Survey of literature relating to infant methemoglobinemia due to nitrate-contaminated water. American Journal of Public Health 41: 986-995. Westerhoff, P. (2003). Reduction of nitrate, bromate, and chlorate by zero valent iron (Fe0). Journal of Environmental Engineering 129: 10-16. Wilkin, R. T. Puls, R. W. and Sewell, G. W. (2003). Long-term performance of permeable reactive barriers using zero- valent iron : geochemical and microbiological effects. Ground Water 41: 493-503. Yang, G. C. C. and Lee, H. L. (2005). Chemical reduction of nitrate by nanosized iron: kinetics and pathways. Water Research 39: 884-894. Zhou, P., Huang, J. C., Li, A. W. F. and Wei, S. (1999). Heavy metal removal from wastewater in fluidized bed reactor. Water Research 33: 1918-1924.; https://ir.cnu.edu.tw/handle/310902800/22851; https://ir.cnu.edu.tw/bitstream/310902800/22851/2/index.html

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16
Dissertation/ Thesis
黑色素形成機轉之細胞模式建立 ; Establishment of a cellular model for the mechanism of melanogenesis

Authors: 黃聖哲, Sheng-che Huang

Contributors: 林清宮, 嘉南藥理科技大學:化妝品科技研究所

Subject Terms: 氯化銨, , 黑色素生成, 酪胺酸酶, H2組織胺受體阻斷劑, ammonium chloride, H2 blocker, tyrosinase, melanogenesis, mulberry

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Relation: 校內校外均不公開; 1. 光井武夫編, 鄭慧文, and 陳韋達譯. 新化粧品學. 合記書局, 2000. 2. 洪偉章, 李金枝, and 陳榮秀. 化妝品原料及弁? 藝宣圖書出版社, 2002. 3. Slominski, A., Tobin, D.J., Shibahara, S., and Wortsman, J. Melanin pigmentation in mammalian skin and its hormonal regulation. Physiol Rev 84(4):1155-228, 2004. 4. Abdel-Malek, Z., Swope, V., Collins, C., Boissy, R., Zhao, H., and Nordlund, J. Contribution of melanogenic proteins to the heterogeneous pigmentation of human melanocytes. J Cell Sci 106 ( Pt 4):1323-31, 1993. 5. Staricco, R.J., and Pinkus, H. Quantitative and qualitative data on the pigment cells of adult human epidermis. J Invest Dermatol 28(1):33-45, 1957. 6. Ancans, J., Tobin, D.J., Hoogduijn, M.J., Smit, N.P., Wakamatsu, K., and Thody, A.J. Melanosomal pH controls rate of melanogenesis, eumelanin/phaeomelanin ratio and melanosome maturation in melanocytes and melanoma cells. Exp Cell Res 268(1):26-35, 2001. 7. Winder, A.J., and Harris, H. New assays for the tyrosine hydroxylase and dopa oxidase activities of tyrosinase. Eur J Biochem 198(2):317-26, 1991. 8. Thody, A.J., Higgins, E.M., Wakamatsu, K., Ito, S., Burchill, S.A., and Marks, J.M. Pheomelanin as well as eumelanin is present in human epidermis. J Invest Dermatol 97(2):340-4, 1991. 9. Hunt, G., Kyne, S., Ito, S., Wakamatsu, K., Todd, C., and Thody, A. Eumelanin and phaeomelanin contents of human epidermis and cultured melanocytes. Pigment Cell Res 8(4):202-8, 1995. 10. Riley, P.A. Melanin. Int J Biochem Cell Biol 29(11):1235-9, 1997. 11. Lerner, A.B., and Fitzpatrick, T.B. Biochemistry of melanin formation. Physiol Rev 30(1):91-126, 1950. 12. Riley, P.A. Tyrosinase kinetics: a semi-quantitative model of the mechanism of oxidation of monohydric and dihydric phenolic substrates. J Theor Biol 203(1):1-12, 2000. 13. Seiji, M., and Iwashita, S. Intracellular localization of tyrosinase and site of melanin formation in melanocyte. J Invest Dermatol 45(5):305-14, 1965. 14. Herzberg, J.J. [On the source of hair melanocytes in the catagen and telogen]. Arch Klin Exp Dermatol 229(2):161-9, 1967. 15. Fuller, B.B., Spaulding, D.T., and Smith, D.R. Regulation of the catalytic activity of preexisting tyrosinase in black and Caucasian human melanocyte cell cultures. Exp Cell Res 262(2):197-208, 2001. 16. Iwata, M., Corn, T., Iwata, S., Everett, M.A., and Fuller, B.B. The relationship between tyrosinase activity and skin color in human foreskins. J Invest Dermatol 95(1):9-15, 1990. 17. Iozumi, K., Hoganson, G.E., Pennella, R., Everett, M.A., and Fuller, B.B. Role of tyrosinase as the determinant of pigmentation in cultured human melanocytes. J Invest Dermatol 100(6):806-11, 1993. 18. Naeyaert, J.M., Eller, M., Gordon, P.R., Park, H.Y., and Gilchrest, B.A. Pigment content of cultured human melanocytes does not correlate with tyrosinase message level. Br J Dermatol 125(4):297-303, 1991. 19. Rungta, D., Corn, T.D., and Fuller, B.B. Regulation of tyrosinase mRNA in mouse melanoma cells by alpha-melanocyte-stimulating hormone. J Invest Dermatol 107(5):689-93, 1996. 20. Fuller, B.B., Rungta, D., Iozumi, K., et al. Hormonal regulation of melanogenesis in mouse melanoma and in human melanocytes. Ann N Y Acad Sci 680:302-19, 1993. 21. Pomerantz, S.H. Tyrosine hydroxylation catalyzed by mammalian tyrosinase: an improved method of assay. Biochem Biophys Res Commun 16(2):188-94, 1964. 22. Stevens, T.H., and Forgac, M. Structure, function and regulation of the vacuolar (H+)-ATPase. Annu Rev Cell Dev Biol 13:779-808, 1997. 23. D'Souza, S., Garcia-Cabado, A., Yu, F., et al. The epithelial sodium-hydrogen antiporter Na+/H+ exchanger 3 accumulates and is functional in recycling endosomes. J Biol Chem 273(4):2035-43, 1998. 24. Counillon, L., and Pouyssegur, J. The expanding family of eucaryotic Na(+)/H(+) exchangers. J Biol Chem 275(1):1-4, 2000. 25. Anraku, Y., Hirata, R., Wada, Y., and Ohya, Y. Molecular genetics of the yeast vacuolar H(+)-ATPase. J Exp Biol 172:67-81, 1992. 26. Ancans, J., Hoogduijn, M.J., and Thody, A.J. Melanosomal pH, pink locus protein and their roles in melanogenesis. J Invest Dermatol 117(1):158-9, 2001. 27. Brilliant, M.H. The mouse p (pink-eyed dilution) and human P genes, oculocutaneous albinism type 2 (OCA2), and melanosomal pH. Pigment Cell Res 14(2):86-93, 2001. 28. Burchill, S.A., Virden, R., and Thody, A.J. Regulation of tyrosinase synthesis and its processing in the hair follicular melanocytes of the mouse during eumelanogenesis and phaeomelanogenesis. J Invest Dermatol 93(2):236-40, 1989. 29. Dexter, T.J., and Bennett, D.C. Differentiation apparently repressed by the nucleus. Rapidly-induced pigmentation of enucleated melanoma cells. Exp Cell Res 168(1):255-64, 1987. 30. Burchill, S.A., Bennett, D.C., Holmes, A., and Thody, A.J. 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Production and utilization of hydrogen peroxide associated with melanogenesis and tyrosinase-mediated oxidations of DOPA and dopamine. FEBS J 272(10):2407-15, 2005. 56. Jimenez, M., and Garcia-Carmona, F. Hydroxylating activity of tyrosinase and its dependence on hydrogen peroxide. Arch Biochem Biophys 373(1):255-60, 2000. 57. Smith, D.R., Spaulding, D.T., Glenn, H.M., and Fuller, B.B. The relationship between Na+/H+ exchanger expression and tyrosinase activity in human melanocytes. Experimental Cell Research 298(2):521-34, 2004.; https://ir.cnu.edu.tw/handle/310902800/9757; https://ir.cnu.edu.tw/bitstream/310902800/9757/1/index.html

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Dissertation/ Thesis
應用潛流式人工濕地淨化大樓景觀水池水質之可行性研究 ; Feasibility Study of Subsurface Constructed Wetland on Water Purification of Landscaping Pond

Authors: 呂建樟, Chien-Chang Lu

Contributors: 錢紀銘, 嘉南藥理科技大學:環境工程與科學系碩士班

Subject Terms: 潛流式人工濕地, 生化需氧量, 氨氮, 總磷, 景觀水池, ammonium nitrogen, total phosphorus, subsurface constructed wetland, landsaping pond, biochemical oxygen demand

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