教授、博士生导师
长江学者、国家杰青、
云岭英才计划高层次人才
邮件:lqma@nju.edu.cn
研究背景概述
马奇英教授主要从事土壤–水体–植物–微生物系统中重金属和有机污染物的生物地球化学及污染土壤、水和废弃物的植物–微生物–化学修复,并取得了较好的效果。马教授于2001年在国际顶级学术刊物《Nature》上报道了世界上第一种砷超富集植物蜈蚣草(Pteris vittata),Web of Science单篇引用达1000余次,Scholar Google引用达1400余次。该发现为砷污染土壤及水体的植物修复提供了可能,拥有6个美国修复技术专利,并产生了较好的经济效益。至今已在Nature, Environmental Science & Technology, Environment International, Journal of Biological Chemistry, New Phytologist, Plant Cell & Environment, Journal of Hazardous Materials, Journal of Environmental Quality, Chemosphere, Environmental Pollution, Science of the Total Environment和Plant and Soil等国际杂志发表SCI论文300多篇,合作出版专著1部《In-Situ Remediation of Arsenic-Contaminated Sites》,编写章节20余篇,得到国际同行的认可。主持国家重点研发计划、国家自然科学基金重点项目、国家自然科学基金面上项目等10余项。马奇英教授是云南省高层次创新创业团队负责人、云南省山地农村生态环境演变与污染治理重点实验室实验室主任、西南林业大学环境修复与健康研究院院长、西南林业大学土壤污染与修复研究中心主任。马奇英教授课题组目前主要开展重金属与有机污染物的环境行为、迁移转化、生物有效性和生态效应,以及环境污染的植物、微生物与化学修复等方面的研究工作。
教育背景
1989/01–1991/05 美国科罗拉多州立大学 土壤环境化学 博士
1985/09–1988/12 美国科罗拉多州立大学 土壤环境化学 硕士
1981/09–1985/07 沈阳农业大学 土壤农业化学 学士
工作经历
2017-至今 西南林业大学生态与环境学院 教授
2015–至今 International Institute of Environmental Studies (IIES) 中方主任
2012–2016 南京大学环境学院 教授
2012–2015 南京大学环境学院环境科学系 主任
2003–2012 美国佛罗里达大学土壤与水科学系 教授
1999–2003 美国佛罗里达大学土壤与水科学系 副教授
1994–1999 美国佛罗里达大学土壤与水科学系 助理教授
1991–1993 美国俄亥俄州立大学自然资源学院 博士后
重要奖项
2018 云岭英才计划高层次人才
2007–2009 教育部长江学者讲座教授
2005–2007 国家自然科学基金海外杰出青年基金
2012 美国科学促进会Fellow
2012 佛罗里达大学杰出教授研究基金奖
2007 美国佛罗里达大学优秀教授奖
2004 美国农业部秘书奖
2003 美国佛罗里达大学杰出教授研究基金奖
2003 美国土壤科学学会Fellow
2003 美国佛罗里达大学Sigma Xi 青年教师研究奖
2002 美国佛罗里达大学Gamma Sigma Delta优秀青年教授成就奖
2002 美国农业科学学会Fellow
2001 英国皇家地理学会和欧洲发现网络颁布的《2001发现奖》
学术兼职
杂志编辑/编委
2015–至今 Environment International编委, Environmental Research编委
2012–至今 Environment Science & Technology编委, Chemosphere编委
2012 Journal of Hazardous Materials客座编辑
2010–至今 Journal of Hazardous Materials编委
2008–2015 Environmental and Experimental Botany编委
2005–至今 Science of the Total Environment编委
1999–2001 Journal of Environmental Quality副主编
专家评审组负责人/成员
2012 美国科学促进会专家评审组成员
2011 美国科学促进会专家评审组成员
2009 美国佛罗里达Gamma Sigma Delta 学会主席
2008 美国国家科学基金会, 美国国立卫生研究院专家评审组成员
2006 美国农业部专家评审组负责人
2004 农业部专家评审组成员
2003 农业部专家评审组成员
2002 美国土壤科学学会土壤与环境质量专业委员会主席
主要在研项目
[1] 国家重点研发计划(2016YFD0800801): 重金属超累积植物种质创新、规模化繁种技术与设备研制, 2016/01–2020/12, 300万元
[2] 国家自然科学基金重点项目(21637002): 土壤–水稻体系中砷迁移与阻控及其健康风险研究, 2017/01–2021/12, 291万元
[3] 国家自然科学基金面上项目(41673101): 新型耦合体外方法对污染土壤中铅的人体生物有效性研究, 2017/01–2020/12, 71万元
[4] 云南省山地农村生态环境演变与污染治理重点实验室.2019/01-2012/12,100万元
近3年学术论文:
[1] Xiang Ping, He Rui-Wen, Liu Rong-Yan, Li Man, Gao Peng, Cui Xin-Yi, Li Hongbo, Liu Yungen*, Ma Lena Q*. Cellular responses of normal (HL-7702) and cancerous (HepG2) hepatic cells to dust extract exposure. Chemosphere, 2018, 193:1189-1197. (SCI收录IF=4.208)
[2] Liu Xue, Feng Hua-Yuan, Fu Jing-Wei, Chen Yanshan, Liu Yungen*, Ma Lena Q*. Arsenic-induced nutrient uptake in As-hyperaccumulator Pteris vittata and their potential role to enhance plant growth. Chemosphere, 2018, 198: 425–431. (SCI收录IF=4.208)
[3] Wang Ziquan, Hou Lei, Liu Yungen*, Wang Yan*, Ma Lena Q. Metal contamination in a riparian wetland: distribution, fractionation and plant uptake. Chemosphere, 2018, 200: 587-593. (SCI收录IF=4.208)
[4] da Silva Evandro B., de Oliveira Letuzia M., Wilkie Ann C., Liu Yungen*, Ma Lena Q*. Arsenic removal from As-hyperaccumulator Pteris vittata biomass: Coupling extraction with precipitation. Chemosphere, 2018, 193:288-294. (SCI收录IF=4.208)
[5] de Oliveira Letuzia M, Das Suchismita, da Silva Evandro B, Gao Peng, Vardanyan Lilit, Liu Yungen*, Ma Lena Q*. Interactive effects of chromate and arsenate on their uptake and speciation in Pteris ensiformis. Plant and Soil, 2018, 422(1-2):515-526. (SCI 收录 IF=3.052)
[6] Chen, Y., Y. H. Han, Y. Cao, Y. G. Zhu, B. Rathinasabapathi*, and L. Q. Ma*. 2017. Arsenic transport in rice and biological solutions to reduce arsenic risk from rice. Frontiers in Plant Science. 8: 268, doi: 10.3389/fpls.2017.00268.
[7] Das, S., L. M. de Oliveira, E. da Silva, L. Q. Ma*. 2017. Arsenate and fluoride enhanced each other’s uptake in As-sensitive plant Pteris ensiformis. Chemosphere. 180: 448–454.
[8] de Oliveira, L. M., D. Suchismita, J. Gress, B. Rathinasabapathi, Y. Chen*, and L. Q. Ma. 2017. Arsenic uptake by lettuce from As-contaminated soil remediated with Pteris vittata and organic amendment. Chemosphere. 176: 249–254.
[9] Fu, J. W., X. Liu, Y. H. Han, H. Mei, Y. Cao, L. M. de Oliveira, Y. Liu, B. Rathinasabapathi, Y. Chen*, and L. Q. Ma. 2017. Arsenic-hyperaccumulator Pteris vittata efficiently solubilized phosphate rock to sustain plant growth and As uptake. J. Hazard. Mater. 330: 68–75.
[10] Gu X., Z. Liu, X. Wang, J. Luo*, H. Zhang, W. Davison, L. Q. Ma, and Y. Xue. 2017. Coupling biological assays with diffusive gradients in thin-films technique to study the biological responses of Eisenia fetida to cadmium in soil. J. Hazard. Mater. 339: 340–346.
[11] Guan, D. X., J. L. Zheng, J. Luo*, H. Zhang, W. Davison, and L. Q. Ma. 2017. A diffusive gradients in thin-films technique for the assessment of bisphenols desorption from soils. J. Hazard. Mater. 331: 321–328.
[12] Han, Y. H., X. Liu, B. Rathinasabapathi, H. B. Li, Y. Chen*, and L. Q. Ma. 2017. Mechanisms of efficient As solubilization in soils and As accumulation by As-hyperaccumulator Pteris vittata. Environ. Pollut. 227: 569–577.
[13] Han, Y. H., J. W. Fu, P. Xiang, Y. Cao, B. Rathinasabapathi, Y. Chen*, and L. Q. Ma*. 2017. Arsenic and phosphate rock impacted the abundance and diversity of bacterial arsenic oxidase and reductase genes in rhizosphere of As-hyperaccumulator Pteris vittata. J. Hazard. Mater. 321: 146–153.
[14] Li, H., X. Dong, E. B. da Silva, L. M. de Oliveira, Y. Chen*, and L. Q. Ma*. 2017. Mechanisms of metal sorption by biochars: Biochar characteristics and modifications. Chemosphere. 178: 466–478.
[15] Li, H. B., J. Li, D. Zhao, C. Li, X. J. Wang, H. J. Sun, A. L. Juhasz, and L. Q. Ma*. 2017. Arsenic relative bioavailability in rice using a mouse arsenic urinary excretion bioassay and its application to assess human health risk. Environ. Sci. Technol. 51: 4689–4696.
[16] Li, K., P. Gao, P. Xiang, X. Zhang, X. Cui*, and L. Q. Ma*. 2017. Molecular mechanisms of PFOA-induced toxicity in animals and humans: Implications for health risks. Environment International. 99: 43–55.
[17] Li, S. W., H. J. Sun, G. Wang, X. Y. Cui, A. L. Juhasz, H. B. Li*, and L. Q. Ma*. 2017. Lead relative bioavailability in soils based on different endpoints of a mouse model. J. Hazard. Mater. 326: 94–100.
[18] Li, S. W., X. Liu, H. J. Sun, M. Y. Li, D. Zhao, J. Luo, H. B. Li*, and L. Q. Ma.2017. Effect of phosphate amendment on relative bioavailability and bioaccessibility of lead and arsenic in contaminated soils. J. Hazard. Mater. 339: 256–263.
[19] Liu, X., J. W. Fu, N. Tang, E. B. da Silva, Y. Cao, B. L. Turner, Y. Chen*, and L. Q. Ma. 2017. Phytate induced arsenic uptake and plant growth in arsenic-hyperaccumulator Pteris vittata. Environ. Pollut. 226: 212–218.
[20] Liu, X., J. W. Fu, E. Da Silva, X. X. Shi, Y. Cao, B. Rathinasabapathi, Y. Chen*, and L. Q. Ma. 2017. Microbial siderophores and root exudates enhanced goethite dissolution and Fe/As uptake by As-hyperaccumulator Pteris vittata. Environ. Pollut. 223: 230–237.
[21] Wang, N., Z. Z. Chang*, X. X. Xue, J. G. Yu, X. X., Shi, L. Q. Ma, and H. B. Li*. 2017. Biochar decreases nitrogen oxide and enhances methane emissions via altering microbial community composition of anaerobic paddy soil. Science Total Environment. 581–582: 689–696.
[22] Xiang, P., R. Y. Liu, C. Li, P. Gao, X. Y. Cui*, and L. Q. Ma*. 2017. Effects of organophosphorus flame retardant TDCPP on normal human corneal epithelial cells: Implications for human health. Environ. Pollut. 230: 22–30.
[23] Xiang, P., R. Y. Liu, H. J. Sun, Y. W. Yang, X. Y. Cui*, and L. Q. Ma*. 2017. Effects of novel brominated flame retardant TBPH and its metabolite TBMEHP to human vascular endothelial cells: Implication for human health risks. Environmental Research. 156: 834–842.
[24] Zhang, S., P. N. Williams, C. Y. Zhou, L. Q. Ma, and J. Luo*. 2017. Extending the functionality of the slurry ferrihydrite-DGT method: Performance evaluation for the measurement of vanadate, arsenate, antimonate and molybdate in water. Chemosphere. 184: 812–819.
[25] Zhang, S., C. Li, Y. Li, R. Zhang, P. Gao, X. Cui*, and L. Q. Ma. 2017. Bioaccessibility of PAHs in contaminated soils: Comparison of five in vitro methods with Tenax as a sorption sink. Science Total Environment. 601–602: 968–974.
[26] Zhao, D., R. Y. Liu, P. Xiang, A. L. Juhasz, L. Huang, J. Luo, H. B. Li*, and L. Q. Ma. 2017. Applying cadmium relative bioavailability to assess dietary intake from rice to predict cadmium urinary excretion in nonsmokers. Environ. Sci. Technol. 51: 6756–6764.
[27] Chen, Y.S.p, JW Fu, Y.H. Han, B. Rathinasabapathi, and L.Q. Ma. 2016. High As exposure induced
substantial arsenite efflux in As-hyperaccumulator Pteris vittata. Chemosphere. 144:2189-2191.
[28] de Oliveira, L.M.p, J. Gress, J. De, B. Rathinasabapathi, G. Marchi, Y. Chen and, L.Q. Ma. 2016. Sulfate and chromate increased each other’s uptake and translocation in As-hyperaccumulator Pteris vittata. Chemosphere. 147:36-43.
[29] Cui, X.Y., P. Xiang, A. Juhasz, and L.Q. Ma. 2016. Advances in in vitro methods to evaluate oral bioaccessibility of PAHs and PBDEs in environmental matrices. Chemosphere. 150:378-389.
[30] Gress, J.g, E.B. da Silva, L.M. de Oliveira, D. Zhao, G. Anderson, D. Heard, L.D. Stuchal and, L.Q. Ma. 2016. Potential arsenic exposures in 25 species of zoo animals living in CCA-wood enclosures. Sci. Total Environment. 551–552:614–621.
[31] Guan, Dg, P.N Williams, H.C Xu, G. Li, J. Luo, and L.Q. Ma. 2016. High-resolution measurement and mapping of tungstate in waters, soils and sediments using the low-disturbance DGT sampling technique. J Hazard Mater. 316:69–76.
[32] Han, Y.H.g, G.M. Yang, JW Fu, D.X. Guan, Y.S. Chen, and L.Q. Ma. 2016. Arsenic-induced plant growth of arsenic-hyperaccumulator Pteris vittata: Impact of arsenic and phosphate rock. Chemosphere. 149:366-372.
[33] Han, Y.H.g, JW Fu, Chen, Y.S., B. Rathinasabapathi, and L.Q. Ma. 2016. Arsenic uptake, arsenite efflux and plant growth in hyperaccumulator Pteris vittata: role of arsenic-resistant bacteria. Chemosphere. 144:1937-1942.
[34] He, R.g, Y. Li, P. Xiang, C. Li, C. Zhou, S. Zhang, X. Cui, and L.Q. Ma. 2016. Organophosphorus flame retardants and phthalate esters in indoor dust from different environments: bioaccessibility and risk assessment. Chemosphere. 150:528-535.
[35] Li, C.g, H-J. Sun, A.L Juhasz, X.Y. Cui and L.Q. Ma. 2016. Predicting the relative bioavailability of DDT and its metabolites in historically contaminated soils using a Tenax-improved physiologically based extraction test (TI-PBET). Environ. Sci. Technol. 50:1118-1125.
[36] Li, HB.p., D. Zhao, J. Li, SW. Li, N. Wang, A. Juhasz, YG. Zhu, and L.Q. Ma. 2016. Using the SBRC assay to predict lead relative bioavailability in urban soils: contaminant source and correlation model. Environ. Sci. Technol. 50:4989-96..
[37] Li, J.g, C. Li, H-J. Sun, A.L. Juhasz, J. Luo, H.B. Li, and L.Q. Ma. 2016. Arsenic relative bioavailability in contaminated soils: comparison of animal models, dosing schemes, and biological end points. Environ. Sci. Technol. 50:453-461.
[38] Li, S.g, H Li, J Luo, H. Li, X. Qian, M. Liu, J. Bi, X. Cui, and L.Q. Ma. 2016. Influence of pollution control on lead inhalation bioaccessibility in PM2.5: a case study of 2014 Youth Olympic Games in Nanjing. Environ. Int. 94:69–75.
[39] Li, S.g, HJ Sun, H Li, J Luo, and L.Q. Ma. 2016. Assessment of cadmium bioaccessibility to predict its bioavailability in contaminated soils. Environ. Int. 94: 600–606.
[40] Liang, S.g, D-X Guan, J. Li, C-Y Zhou, J. Luo and L.Q. Ma. 2016. Effect of aging on bioaccessibility of arsenic and lead in soils. Chemosphere. 151:94-100.
[41] Liu, X.g, JW Fu, DX Guan, Y Cao, J Luo, B Rathinasabapathi, Y. Chen, and L.Q. Ma. 2016. Arsenic induced phytate exudation, and promoted FeAsO4 dissolution and plant growth in As-hyperaccumulator Pteris vittata. Environ. Sci. Technol. In press.
[42] Sun, H.J.g, P. Xiang, M.H. Tang, L. Sun and L.Q. Ma. 2016. Arsenic impacted the development, thyroid hormone and gene transcription of thyroid hormone receptors in bighead carp larvae (Hypophthalmichthys nobilis). J Hazard Mater. 303:76-82.
[43] Wang, C., X. Cui, Y. Li, H. Li, L. Huang, J.Bi, J. Luo, L.Q. Ma, W. Zhou, Y. Cao, B. Wang & F. Miao. 2016. A label-free and portable graphene FET aptasensor for children blood lead detection. Scientific Reports. 6: 21711.
[44] Xiang, P.g, R.W. He, Y.H. Han, H.J. Sun, X.Y. Cui and L.Q. Ma. 2016. Mechanisms of housedust-induced toxicity in primary human corneal epithelial cells: Oxidative stress, proinflammatory response and mitochondrial dysfunction. Environ. Int. 89–90:30–37.
[45] Xiang, P.g, RY. Liu, HJ. Sun, Y.H. Han, R.W. He, X.Y. Cui and L.Q. Ma. 2016. Molecular mechanisms of dust-induced toxicity in human corneal epithelial cells: Water and organic extract of office and house dust. Environ. Int. 92–93:348–356.
[46] Xu, JY.g, Y.H. Han, Chen, Y.S., L.J. Zhu, and L.Q. Ma. 2016. Arsenic transformation and plant growth promotion characteristics of As-resistant endophytic bacteria from As-hyperaccumulator Pteris vittata. Chemosphere 144: 1233–1240.
[47] Zhang, K.M., Y. Shen, X.Q. Zhou, Y.M. Fang, Y. Liu, and L.Q. Ma. 2016. Photosynthetic electron-transfer reactions in the gametophyte of Pteris multifida reveal the presence of allelopathic interference from the invasive plant species Bidens pilosa. J Photochemistry Photobiology 158: 81–88
[48] Zhao, D.g, J Li, C Li, AL. Juhasz, KG. Scheckel, J Luo, HB Li, and L.Q. Ma. 2016. Lead relative bioavailability in lip products and their potential health risk to women. Environ. Sci. Technol 50:6036-6043
[49] Zhou, C.Y.g, DX Guan, PN Williams, J.Luo and L.Q. Ma. 2016. Novel DGT method with tri-metal oxide adsorbent for in situ spatiotemporal flux measurement of fluoride in waters and sediments. Water Research. 99:200-208