參考文獻 |
[1] S. Veli, B. Alyuz, Adsorption of copper and zinc from aqueous solutions by using natural clay, J Hazard Mater 149(1) (2007) 226-33.
[2] N. Wang, Y. Han, Y. Liu, T. Bai, H. Gao, P. Zhang, W. Wang, W. Liu, High-strength hydrogel as a reusable adsorbent of copper ions, J Hazard Mater 213-214 (2012) 258-64.
[3] M. Monier, D.M. Ayad, A.A. Sarhan, Adsorption of Cu(II), Hg(II), and Ni(II) ions by modified natural wool chelating fibers, J Hazard Mater 176(1-3) (2010) 348-55.
[4] F. Fu, Q. Wang, Removal of heavy metal ions from wastewaters: a review, J Environ Manage 92(3) (2011) 407-18.
[5] S. Zhu, N. Yang, D. Zhang, Poly(N,N-dimethylaminoethyl methacrylate) modification of activated carbon for copper ions removal, Materials Chemistry and Physics 113(2-3) (2009) 784-789.
[6] E.S. Dragan, M.V. Dinu, D. Timpu, Preparation and characterization of novel composites based on chitosan and clinoptilolite with enhanced adsorption properties for Cu2+, Bioresour Technol 101(2) (2010) 812-7.
[7] W. Shen, S. Chen, S. Shi, X. Li, X. Zhang, W. Hu, H. Wang, Adsorption of Cu(II) and Pb(II) onto diethylenetriamine-bacterial cellulose, Carbohydrate Polymers 75(1) (2009) 110-114.
[8] P. Kampalanonwat, P. Supaphol, Preparation and adsorption behavior of aminated electrospun polyacrylonitrile nanofiber mats for heavy metal ion removal, ACS Appl Mater Interfaces 2(12) (2010) 3619-27.
[9] H. Kaşgöz, S. Özgümüş, M. Orbay, Modified polyacrylamide hydrogels and their application in removal of heavy metal ions, Polymer 44(6) (2003) 1785-1793.
[10] T. Trakulsujaritchok, N. Noiphom, N. Tangtreamjitmun, R. Saeeng, Adsorptive features of poly(glycidyl methacrylate-co-hydroxyethyl methacrylate): effect of porogen formulation on heavy metal ion adsorption, Journal of Materials Science 46(16) (2011) 5350-5362.
[11] P.G. Georgopoulos, A. Roy, M.J. Yonone-Lioy, R.E. Opiekun, P.J. Lioy, Environmental copper: its dynamics and human exposure issues, J Toxicol Environ Health B Crit Rev 4(4) (2001) 341-94.
[12] X.-s. Wang, Y. Qin, Equilibrium sorption isotherms for of Cu2+ on rice bran, Process Biochemistry 40(2) (2005) 677-680.
[13] H.K. Elena Gaggelli, Daniela Valensin, and Gianni Valensin, Copper Homeostasis and Neurodegenerative Disorders (Alzheimer’s, Prion, and Parkinson’s Diseases and Amyotrophic Lateral Sclerosis), Chem. Rev. 106(1995−2044) (2006).
[14] R. Squitti, R. Polimanti, Copper phenotype in Alzheimer′s disease: dissecting the pathway, Am J Neurodegener Dis 2(2) (2013) 46-56.
[15] J. Tennant, M. Stansfield, S. Yamaji, S.K. Srai, P. Sharp, Effects of copper on the expression of metal transporters in human intestinal Caco-2 cells, FEBS Lett 527(1-3) (2002) 239-44.
[16] M.D. Knutson, Steap proteins: implications for iron and copper metabolism, Nutr Rev 65(7) (2007) 335-40.
[17] M. Greenough, L. Pase, I. Voskoboinik, M.J. Petris, A.W. O′Brien, J. Camakaris, Signals regulating trafficking of Menkes (MNK; ATP7A) copper-translocating P-type ATPase in polarized MDCK cells, Am J Physiol Cell Physiol 287(5) (2004) C1463-71.
[18] D.L. de Romana, M. Olivares, R. Uauy, M. Araya, Risks and benefits of copper in light of new insights of copper homeostasis, J Trace Elem Med Biol 25(1) (2011) 3-13.
[19] M. Dijkstra, R.J. Vonk, F. Kuipers, How does copper get into bile? New insights into the mechanism(s) of hepatobiliary copper transport, J Hepatol 24 Suppl 1 (1996) 109-20.
[20] M. Araya, B. Koletzko, R. Uauy, Copper deficiency and excess in infancy: developing a research agenda, J Pediatr Gastroenterol Nutr 37(4) (2003) 422-9.
[21] P. de Bie, P. Muller, C. Wijmenga, L.W. Klomp, Molecular pathogenesis of Wilson and Menkes disease: correlation of mutations with molecular defects and disease phenotypes, J Med Genet 44(11) (2007) 673-88.
[22] E. Nastoulis, M.V. Karakasi, C.M. Couvaris, S. Kapetanakis, A. Fiska, P. Pavlidis, Greenish-blue gastric content: Literature review and case report on acute copper sulphate poisoning, Forensic Sci Rev 29(1) (2017) 77-91.
[23] U. Förstner, Wittmann, G. T. W., Metal Pollution in the Aquatic Environment, Springer Verlag, New York (1981).
[24] 陳偉周、林奐成, 「這裡是麥寮第二」桃園40公里海岸體無完膚, 蘋果日報 (2014).
[25] C.S. Gamakaranage, C. Rodrigo, S. Weerasinghe, A. Gnanathasan, V. Puvanaraj, H. Fernando, Complications and management of acute copper sulphate poisoning; a case discussion, J Occup Med Toxicol 6(1) (2011) 34.
[26] N. Franchitto, P. Gandia-Mailly, B. Georges, A. Galinier, N. Telmon, J.L. Ducasse, D. Rouge, Acute copper sulphate poisoning: a case report and literature review, Resuscitation 78(1) (2008) 92-6.
[27] A. Ala, A.P. Walker, K. Ashkan, J.S. Dooley, M.L. Schilsky, Wilson′s disease, Lancet 369(9559) (2007) 397-408.
[28] Wikipedia, Kayser–Fleischer ring, https://en.wikipedia.org/wiki/Kayser%E2%80%93Fleischer_ring.
[29] E.A. Roberts, M.L. Schilsky, D. American Association for Study of Liver, Diagnosis and treatment of Wilson disease: an update, Hepatology 47(6) (2008) 2089-111.
[30] R.H. Wiesner, R.B. Freeman, D.C. Mulligan, Liver transplantation for hepatocellular cancer: The impact of the MELD allocation policy, Gastroenterology 127(5) (2004) S261-S267.
[31] J.D. Korman, I. Volenberg, J. Balko, J. Webster, F.V. Schiodt, R.H. Squires, Jr., R.J. Fontana, W.M. Lee, M.L. Schilsky, Pediatric, G. Adult Acute Liver Failure Study, Screening for Wilson disease in acute liver failure: a comparison of currently available diagnostic tests, Hepatology 48(4) (2008) 1167-74.
[32] B. Kreymann, M. Seige, U. Schweigart, K.F. Kopp, M. Classen, Albumin dialysis: effective removal of copper in a patient with fulminant Wilson disease and successful bridging to liver transplantation: a new possibility for the elimination of protein-bound toxins, J Hepatol 31(6) (1999) 1080-5.
[33] M. Bilal, J.A. Shah, T. Ashfaq, S.M. Gardazi, A.A. Tahir, A. Pervez, H. Haroon, Q. Mahmood, Waste biomass adsorbents for copper removal from industrial wastewater--a review, J Hazard Mater 263 Pt 2 (2013) 322-33.
[34] A.L. Ahmad, B.S. Ooi, A study on acid reclamation and copper recovery using low pressure nanofiltration membrane, Chemical Engineering Journal 156(2) (2010) 257-263.
[35] Z.V. Murthy, L.B. Chaudhari, Application of nanofiltration for the rejection of nickel ions from aqueous solutions and estimation of membrane transport parameters, J Hazard Mater 160(1) (2008) 70-7.
[36] Y. Luo, M.S. Shoichet, A photolabile hydrogel for guided three-dimensional cell growth and migration, Nat Mater 3(4) (2004) 249-53.
[37] S.M. Ibrahim, K.M. El Salmawi, A.H. Zahran, Synthesis of crosslinked superabsorbent carboxymethyl cellulose/acrylamide hydrogels through electron-beam irradiation, Journal of Applied Polymer Science 104(3) (2007) 2003-2008.
[38] A. Sannino, C. Demitri, M. Madaghiele, Biodegradable Cellulose-based Hydrogels: Design and Applications, Materials 2(2) (2009) 353-373.
[39] W.B. Wang, D.J. Huang, Y.R. Kang, A.Q. Wang, One-step in situ fabrication of a granular semi-IPN hydrogel based on chitosan and gelatin for fast and efficient adsorption of Cu2+ ion, Colloids Surf B Biointerfaces 106 (2013) 51-9.
[40] G. Zhou, C. Liu, L. Chu, Y. Tang, S. Luo, Rapid and efficient treatment of wastewater with high-concentration heavy metals using a new type of hydrogel-based adsorption process, Bioresour Technol 219 (2016) 451-457.
[41] Q. Liu, A. Singh, L. Liu, Amino acid-based zwitterionic poly(serine methacrylate) as an antifouling material, Biomacromolecules 14(1) (2013) 226-31.
[42] B. Jiang, J.C. Larson, P.W. Drapala, V.H. Perez-Luna, J.J. Kang-Mieler, E.M. Brey, Investigation of lysine acrylate containing poly(N-isopropylacrylamide) hydrogels as wound dressings in normal and infected wounds, J Biomed Mater Res B Appl Biomater 100(3) (2012) 668-76.
[43] W. Xu, J. Qian, Y. Zhang, A. Suo, N. Cui, J. Wang, Y. Yao, H. Wang, A double-network poly(Nvarepsilon-acryloyl L-lysine)/hyaluronic acid hydrogel as a mimic of the breast tumor microenvironment, Acta Biomater 33 (2016) 131-41.
[44] C.J. Huang, L.C. Wang, C.Y. Liu, A.S. Chiang, Y.C. Chang, Natural zwitterionic organosulfurs as surface ligands for antifouling and responsive properties, Biointerphases 9(2) (2014) 029010.
[45] Q. Liu, W. Li, A. Singh, G. Cheng, L. Liu, Two amino acid-based superlow fouling polymers: poly(lysine methacrylamide) and poly(ornithine methacrylamide), Acta Biomater 10(7) (2014) 2956-64.
[46] Y. Xu, X. Yang, S. Zhu, Y. Dou, Selectively fluorescent sensing of Cu2+ based on lysine-functionalized gold nanoclusters, Colloids and Surfaces A: Physicochemical and Engineering Aspects 450 (2014) 115-120.
[47] S. Nagaoka, A. Shundo, T. Satoh, K. Nagira, R. Kishi, K. Ueno, K. Iio, H. Ihara, Method for a Convenient and Efficient Synthesis of Amino Acid Acrylic Monomers with Zwitterionic Structure, Synthetic Communications 35(19) (2006) 2529-2534.
[48] K.-T. Huang, Y.-L. Fang, P.-S. Hsieh, C.-C. Li, N.-T. Dai, C.-J. Huang, Zwitterionic nanocomposite hydrogels as effective wound dressings, Journal of Materials Chemistry B 4(23) (2016) 4206-4215.
[49] C. Cheng, S. Nie, S. Li, H. Peng, H. Yang, L. Ma, S. Sun, C. Zhao, Biopolymer functionalized reduced graphene oxide with enhanced biocompatibility via mussel inspired coatings/anchors, J. Mater. Chem. B 1(3) (2013) 265-275.
[50] R. Musacco-Sebio, N. Ferrarotti, C. Saporito-Magrina, J. Semprine, J. Fuda, H. Torti, A. Boveris, M.G. Repetto, Oxidative damage to rat brain in iron and copper overloads, Metallomics 6(8) (2014) 1410-6.
[51] M. Karbarz, K. Pulka, A. Misicka, Z. Stojek, pH and temperature-sensitive N-isopropylacrylamide ampholytic networks incorporating L-lysine, Langmuir 22(18) (2006) 7843-7.
[52] L. Zhou, X. Chen, W. Dai, Z. Shao, X-ray photoelectron spectroscopic and Raman analysis of silk fibroin-Cu(II) films, Biopolymers 82(2) (2006) 144-51.
|