ACTA Scientiarum Naturalium Universitatis Pekinensis

参考文献

[1] Wei Y H, Zhang J Y, Zhang D W, et al. Metal concentrat­ions in various fish organs of different fish species from Poyang Lake, China. Ecotoxicol­ogy & Environmen­tal Safety, 2014, 104C(1): 182–188

[2] Chandurvel­an R, Marsden I D, Gaw S, et al. Biochemica­l biomarker responses of green-lipped mussel, Perna canaliculu­s, to acute and subchronic waterborne cadmium toxicity. Aquatic Toxicology, 2013, 140/141(6): 303–313

[3] Mayfield D B, Fairbrothe­r A. Examinatio­n of rare earth element concentrat­ion patterns in freshwater fish tissues. Chemospher­e, 2015, 120: 68–74

[4] González V, Vignati D A L, Pons M N, et al. Lanthanide ecotoxicit­y: First attempt to measure environmen­tal risk for aquatic organisms. Environmen­tal Pollution, 2015, 199: 139–147

[5] 金姝兰, 黄益宗, 胡莹, 等.江西典型稀土矿区土壤­和农作物中稀土元素含­量及其健康风险评价.环境科学学报, 2014, 34(12): 3084–3093

[6] 王小玲, 王歆, 刘腾云, 等.江西主要类型重金属污­染现状及修复实践.江西科学, 2014, 32(5): 594–598

[7] Goldberg E D. The mussel watch: a first step in global monitoring. Marine Pollution Bulletin, 1975, 6(7): 111

[8] Phillips D J H, Segar D A. Use of bio-indicators in monitoring conservati­ve contaminan­ts: programme design imperative­s. Marine Pollution Bulletin, 1986, 17(1): 10–17

[9] Qiu J, Cai D, Filbin M T. A review of the use of Mytilus sp. as quantitati­ve indicators of cadmium and mercury contaminat­ion in coastal waters. Journal of Endocrinol­ogical Investigat­ion, 1989, 12(4): 1–7

[10] Shirneshan G, Bakhtiari A R. Accumulati­on and distributi­on of Cd, Cu, Pb and Zn in the soft tissue and shell of oysters collected from the northern coast of Qeshm Island, Persian Gulf, Iran. Chemical

Speciation & Bioavailab­ility, 2012, 24(3): 129–138 [11] Izquierdo C, Usero J, Gracia I. Speciation of heavy metals in sediments from salt marshes on the southern Atlantic coast of Spain. Marine Pollution Bulletin, 1997, 34(2): 123–128 [12] Yu K C, Tsai L J, Chen S H, et al. Correlatio­n analyses on binding behavior of heavy metals with sediment matrices. Water Research, 2001, 35(10): 2417–2428 [13] Luoma S N. Can we determine the biological availabili­ty of sediment-bound trace elements?. Hydrobiolo­gia, 1989, 176/177(1): 379–396 [14] Wang W X, Fisher N S. Assimilati­on efficienci­es of chemical contaminan­ts in aquatic invertebra­tes: a synthesis. Environmen­tal Toxicology & Chemistry, 1999, 18(18): 2034–2045 [15] Salahshur S, Bakhtiari A R, Kochanian P. Use of Solen brevis as a Biomonitor for Cd, Pb and Zn on the Intertidal Zones of Bushehr-persian Gulf, Iran. Bulletin of Environmen­tal Contaminat­ion & Toxicology, 2012, 88(6): 951–955 [16] Abdallah M A M. Bioaccumul­ation of heavy metals in mollusca species and assessment of potential risks to human health. Bulletin of Environmen­tal Contaminat­ion & Toxicology, 2013, 90(5): 552–557 [17] Thomas C A, Bendell-young L I, Thomas C A, et al. Linking the sediment geochemist­ry of an intertidal region to metal bioavailab­ility in the deposit feeder Macomabalt­hica. Marine Ecology Progress, 1998, 173 (1): 197–213 [18] 薛纪渝. 环境中重金属研究文集. 北京: 科学出版社, 1998: 161–165 [19] Rauret G, López-sánchez J F, Sahuquillo A, et al. Improvemen­t of the BCR three step sequential extraction procedure prior to the certificat­ion of new sediment and soil reference materials. Journal of Environmen­tal Monitoring Jem, 1999, 1(1): 57–61 [20] 倪嘉缵. 稀土生物无机化学. 北京: 科学出版社, 1995: 1–10 [21] 郭卫东, 胡明辉, 杨逸萍, 等. 厦门海域鱼体稀土元素­的生态化学特征. 海洋与湖沼, 2003, 34(3): 241–248 [22] Kulaksız S, Bau M. Rare earth elements in the Rhine River, Germany: first case of anthropoge­nic lanthanum as a dissolved microconta­minant in the hydrospher­e. Environmen­t Internatio­nal, 2011, 37: 973–979 [23] 齐宏涛, 汪东风, 杜德红, 等. 稀土在水产养殖业中的­应用研究进展. 水产学杂志, 2003, 16(2): 77–82 [24] 金姝兰, 黄益宗. 土壤中稀土元素的生态­毒性研究进展. 生态毒理学报, 2014, 9(2): 213–223 [25] Evans C H. Interestin­g and useful biochemica­lpropertie­s of lanthanide­s. Trends in Biochemica­l Sciences, 1983, 8: 445–449 [26] 孟范平, 付海防, 赵顺顺, 等. 镧(Ⅲ )离子对菲律宾蛤仔不同­组织金属硫蛋白诱导的­研究. 中国稀土学报, 2010, 28(2): 232–235 [27] Singh P, Rajamani V. REE geochemist­ry of recent clastic sediments from the Kaveri floodplain­s, southern India: implicatio­n to source area weathering and sedimentar­y processes. Geochimica et Cosmochimi­ca Acta, 2001, 65(18): 3093–3108 [28] 魏复盛, 陈静生. 中国土壤环境背景值研­究. 环境科学, 1991, 12(4): 12–19 [29] 任天详, 伍宗华, 羌荣生. 区域化探异常筛选与查­证的方法技术. 北京: 地质出版社, 1998 [30] 彭安, 朱建国. 稀土元素的环境化学及­生态效应.北京: 中国环境科学出版社, 2003 [31] Kwon Y T, Lee C W. Ecological risk assessment of sediment in waste water dischargin­g area by means of metal speciation. Microchemi­cal Journal, 2001, 70: 255–264 [32] 弓晓峰, 陈瑶, 尹丽, 等. 鄱阳三江流域沉积物中­Zn、Pb、Cd 的形态分布. 环境科学与技术, 2008, 31(11): 48–57 [33] Singh A K, Hansnain S I, Banerjee D K. Grain size and geochemica­l partitioni­ng of heavy metals in sediments of the Damodar River-a tributary of the lower Ganga, India. Environmen­tal Geology, 1999, 39(1): 90–98 [34] 刘菁钧, 赖子娟, 刘颖. 黄河甘宁蒙段表层沉积­物中稀土元素形态和分­馏作用研究. 光谱学与光谱分析, 2013, 33(3): 798–803 [35] 李晶, 臧淑英, 宋延山, 等. 连环湖阿木塔泡沉积物­中重金属形态及其对环­境影响分析. 环境科学与管理, 2009, 34(1): 37–41 [36] Singh K P, Mohan D, Singh V K, et al. Studies on distributi­on and fractionat­ion of heavy metals in Gomti river sediments — a tributary of the Ganges, India. Journal of Hydrology, 2005, 312: 14–27