馬奇英

馬奇英

浙江大學環境與資源學院教授、博士生導師。

1985年獲瀋陽農業大學土壤農業化學學士學位;1991年獲美國科羅拉多州立大學土壤環境化學博士學位。2001年在《自然》雜誌報導世界上第一個砷超富集植物蜈蚣草並引領其在砷污染場地植物修復的套用。

主要從事重金屬的生物地球化學與環境修複方面的研究工作,主要包括重金屬的人體生物有效性,植物修復與食品安全。

基本介紹

  • 中文名:馬奇英
  • 外文名:Lena Qiying Ma
  • 畢業院校:美國科羅州立拉多大學 (博士)
  • 職業:教學科研工作者
  • 主要成就:發現砷超富集植物蜈蚣草
人物經歷,主要成就,

人物經歷

學士(BS) 1985 中國 瀋陽農業大學 土壤農業化學
馬奇英
馬奇英
碩士(MS) 1988 美國 科羅拉多州立大學 土壤環境化學
博士(PhD) 1991 美國 科羅拉多州立大學 土壤環境化學
博士後 1991-1993 美國 俄亥俄州立大學自然資源學院
助理教授 1994-1999 美國 佛羅里達大學土壤與水科學系
副教授 1999-2003 美國 佛羅里達大學土壤與水科學系
教授 2012–2016 南京大學環境學院
主任 2012–2015 南京大學環境學院環境科學系
教授 2003-2019 美國 佛羅里達大學土壤與水科學系
教授 2020至今 中國 浙江大學環境與資源學院

主要成就

長期從事土壤等多環境介質中污染物生物地球化學過程與土壤污染修復治理、污染物在土壤-農產品中的遷移轉化規律與人體生物有效性、典型污染物暴露誘發人體健康效應機制等方面的研究;在污染物(以重金屬為主)的水-土-植物-微生物系統遷移過程與生物轉化、環境風險管控、污染防治技術,土壤重金屬植物吸收有效性、生物累積與人體健康、土壤重金屬污染與食品安全等方面取得系統性科研成果。發表SCI論文近400篇(其中國際頂級學術刊物Nature2篇,國際環境領域頂級刊物Environmental Science & Technology 40餘篇),出版全英文學術專著(含編寫章節)30餘部;獲得美國土壤污染修復技術專利5項。並受邀擔任多個國際會議主席或副主席,先後在國際、國內學術會議作大會報告200餘次。據Web of Science,總引次數1.9餘萬次,H指數為67,高被引科學家
2020 (31)
  • Chen, J., LD. Garbinski, B Rosen, J Zhang, P Xiang & LQ. Ma. 2020. Organoarsenical compounds: Occurrence, toxicology and biotransformation Critical Rev. Environ. Sci. Technol. 50: 217-243
  • Chen, Y., A Juhasz, H Li, C Li, LQ. Ma & X Cui. 2020. The influence of food on the in vivo bioavailability of DDT and its metabolites in soil. Environ. Sci. Technol. 54: 5003-5010.
  • Chen, Y., M Guo, R Liu, LQ. Ma & X Cui. 2020. Effects of novel brominated flame retardants and metabolites on cytotoxicity in human umbilical vein endothelial cells. Chemosphere 253: 126653.
  • Cui, D., J Bi, ZN. Zhang, MY. Li, YS. Qin, P Xiang & LQ. Ma. 2020. Organophosphorus flame retardant TDCPP-induced cytotoxicity and associated mechanisms in normal human skin keratinocytes. Sci. Total Environ. 726: 138526.
  • da Silva, EB., P Gao, M Xu, D Guan, X Tang & LQ. Ma. 2020. Background concentrations of trace metals As, Ba, Cd, Co, Cu, Ni, Pb, Se, and Zn in 214 Florida urban soils: Different cities and land uses. Environ. Pollut. 264: 114737.
  • Deng, F., X Liu, Y Chen, B Rathinasabapathi, C Rensing, J Chen, J. Bi, P, Xiang & LQ Ma. 2020. Aquaporins mediated arsenite transport in plants: Molecular mechanisms and applications in crop improvement. Critical Rev. Environ. Sci. Technol. 50:1613–1639.
  • Han Y, Jia M, Wang S, Deng J, Shi X, Chen D, Chen Y, Ma L. 2020. Arsenic accumulation and distribution in Pteris vittata fronds of different maturity: Impacts of soil As concentrations. Sci. Total Environ. 715:135298
  • He, SX., X Wang, X Wu, YL. Yin & LQ. Ma. 2020. Using rice as a remediating plant to deplete bioavailable arsenic from paddy soils. Environ. Int. 141: 105799.
  • Hua, CY., JX. Chen, Y Cao, HB. Li, Y Chen & LQ. Ma. 2020. Pteris vittata coupled with phosphate rock effectively reduced As and Cd uptake by water spinach from contaminated soil. Chemosphere 247: 125916.
  • Li, C., J Wang, B Yan, AJ. Miao, H Zhong, W Zhang & LQ. Ma. 2020. Understanding of arsenic being a double-edged sword from a scientometric viewpoint. Critical Rev. Environ. Sci. Technol. DOI: 10.1080/10643389.2020.1752611.
  • Li, H., M Li, D Zhao, J Li, S Li, P Xiang, AL. Juhasz & LQ. Ma. 2020. Arsenic, lead, and cadmium bioaccessibility in contaminated soils: Measurements and validations. Critical Rev. Environ. Sci. Technol. 50:1303–1338.
  • Li, HB., JY. Wang, XQ. Chen, YP. Li, J Fan, JH. Ren, XS. Luo, AL. Juhasz & LQ. Ma. 2020. Geogenic nickel exposure from food consumption and soil ingestion: A bioavailability based assessment. Environ. Pollut. 265: 114873.
  • Li, K., Z Liu, X Shi, T Wei, LQ. Ma & J Luo. 2020. Novel in situ method based on diffusive gradients in thin-films with lanthanum oxide nanoparticles for measuring As, Sb, and V and in waters. J. Hazard. Mat. 383: 121196.
  • Li, SW., M Chang, H Li, XY. Cui & LQ. Ma. 2020. Chemical compositions and source apportionment of PM2.5 during clear and hazy days: Seasonal changes and impacts of Youth Olympic Games. Chemosphere 256: 127163.
  • Li, SW., MY. Li, HJ. Sun, HB. Li & LQ. Ma. 2020. Lead bioavailability in different fractions of mining- and smelting-contaminated soils based on a sequential extraction and mouse kidney model. Environ. Pollut. 262: 114253.
  • Li, X., D Sun, H Feng, J Chen, Y Chen, H Li, Y Cao & LQ. Ma. 2020. Efficient arsenate reduction in As-hyperaccumulator Pteris vittata are mediated by novel arsenate reductases PvHAC1 and PvHAC2. J. Hazard. Mater. 399: 122895.
  • Liu, G., L Liao, Z Dai, Q Qi, J Wu, LQ. Ma, C Tang & J Xu. 2020. Organic adsorbents modified with citric acid and Fe3O4 enhance the removal of Cd and Pb in contaminated solutions. Chem. Eng. J. 395: 125108.
  • Ma, Q., W Zhao, DX. Guan, HH. Teng, J Ji & LQ. Ma. 2020. Comparing CaCl2, EDTA and DGT methods to predict Cd and Ni accumulation in rice grains from contaminated soils. Environ. Pollut. 260: 114042.
  • Sun, D., H Feng, X Li, H Ai, S Sun, Y Chen, G Xu, B Rathinasabapathi, Y Cao & LQ. Ma. 2020. Expression of new Pteris vittata phosphate transporter PvPht1;4 reduces arsenic translocation from the roots to shoots in tobacco plants. Environ. Sci. Technol. 54:1045–1053.
  • Sun, W., F Dou, C Li, X Ma & LQ. Ma. 2020. Impacts of metallic nanoparticles and transformed products on soil health. Critical Rev. Environ. Sci. Technol. DOI: 10.1080/10643389.2020.1740546.
  • Wu YY., J Lou, X Sun, LQ. Ma, JY. Wang, MY. Li, H Sun, HB. Li & L Huang. 2020. Linking elevated blood lead level in urban school-aged children with bioaccessible lead in neighborhood soil. Environ. Pollut. 261: 114093.
  • Xiang, P., K Wang, J Bi, M Li, RW. He, D Cui & LQ. Ma. 2020. Organic extract of indoor dust induces estrogen-like effects in human breast cancer cells. Sci. Total Environ. 726: 138505.
  • Xu, W., P Xiang, X Liu & LQ. Ma. 2020. Closely-related species of hyperaccumulating plants and their ability in accumulation of As, Cd, Cu, Mn, Ni, Pb and Zn. Chemosphere 251: 126334.
  • Xu, W., Y. Cao, Y Chen, P Xiang, X Liu & LQ. Ma. 2020. Response to comment on “Closely-related species of hyperaccumulating plants and their ability in accumulation of As, Cd, Cu, Mn, Ni, Pb and Zn”. Chemosphere 260:128037.
  • Yan, K., Z Dong, R Naidu, Y Liu, Y Li, A Wijayawardena, P Sanderson, H Li & LQ Ma. 2020. Comparison of in vitro models in a mice model and investigation of the changes in Pb speciation during Pb bioavailability assessments. J. Hazard. Mat. 388:121744.
  • Yang S., S Gu, M He, X Tang, LQ Ma, J Xu & X Liu. 2020. Policy adjustment impacts Cd, Cu, Ni, Pb and Zn contamination in soils around e-waste area: Concentrations, sources and health risks. Sci. Total Environ. 741: 140442.
  • Yin DX., W Fang, DX. Guan, PN. Williams, E Moreno-Jiménez, Y Gao, FJ. Zhao, LQ. Ma, H Zhang & J Luo. 2020. Localized intensification of arsenic release within the emergent rice rhizosphere. Environ. Sci. Technol. 54: 3138-3147.
  • Zhang H, Wang Q, Xu Q, Xu W, Yang S, Liu X, Ma L. 2020. Sequential fractionation and plant uptake of As, Cu, and Zn in a contaminated riparian wetland. Environ. Pollut. 268:115734
  • Zhang, R., Q Zhang, LQ. Ma & X Cui. 2020. Effects of food constituents on absorption and bioaccessibility of dietary synthetic phenolic antioxidant by Caco-2 cells. J. Agric. Food Chem. 68: 4670-4677.
  • Zhao, D., J Wang, D Yin, M Li, X Chen, AL. Juhasz, J Luo, A Navas-Acien, H Li & LQ. Ma. 2020. Arsanilic acid contributes more to total arsenic than roxarsone in chicken meat from Chinese markets. Environ. Int. 130: 104875.
2019 (22)
  • Abid, R, M. Manzoor, LM. De Oliveira, E da Silva, B Rathinasabapathi, C Rensing, S Mahmood, X Liu, LQ. Ma. 2019. Interactive effects of As, Cd and Zn on their uptake and oxidative stress in As-hyperaccumulator Pteris vittata. Environ. Pollut. 248:756-762.345
  • Chen,Y., C. Hua, JX Chen, B Rathinasabapathi, Y Cao, and LQ. Ma. 2019. Expressing arsenite antiporter PvACR3;1 in Rice (Oryza sativa L.) decreases inorganic arsenic content in rice grains. Environ. Sci. Technol. 53, 10062−10069
  • da Silva a, EB., WA. Mussoline, AC Wilkie, LQ. Ma. 2019. Arsenic removal and biomass reduction of As-hyperaccumulator Pteris vittata: Coupling ethanol extraction with anaerobic digestion. Sic. Total Environ. 666:205–211.
  • da Silva a, EB., WA. Mussoline, AC Wilkie, LQ. Ma. 2019. Anaerobic digestion to reduce biomass and remove arsenic from As-hyperaccumulator Pteris vittata. Environ. Pollut. 250:23-28.
  • Deng, H, M Luo, X Shi, PN. Williams, K Li, M Liu, W Fan, T Xiao, Y Chen, LQ. Ma, and J Luo. 2019. In situ measurement of thallium in natural waters by a technique based on diffusive gradients in thin films containing a δ‑MnO2 gel layer. Anal. Chem. 91:1344−1352.
  • Han, Y., D Yin, M Jia, S Wang, Y Chen, B Rathinasabapathi, D Chen, LQ. Ma. 2019. Arsenic-resistance mechanisms in bacterium Leclercia adecarboxylata strain As3-1: Biochemical and genomic analyses. Sci. Total Environ. 690:1178–1189.
  • Huang, L., L Liu, T Zhang, D Zhao, H Li, H Sun, PL. Kinney, M Pitiranggon, S Chillrud, LQ Ma, A Navas-Acien, J Bi. B Yan. 2019. An interventional study of rice for reducing cadmium exposure in a Chinese industrial town. Environ. Int. 122:301–309.
  • Gao, P., Y. Liu, Y. Wang, X. Liu, Z. Wang, LQ. Ma. 2019. Spatial and temporal changes of P and Ca distribution and fractionation in soil and sediment in a karst farmland-wetland system. Chemosphere. 220:644-650.
  • Gao, P., EB. da Silva, T Townsend, X Liu, LQ Ma. 2019. Emerging PAHs in urban soils: Concentrations, bioaccessibility, and spatial distribution. Science Total Environment 670:800–805.
  • Gao, P., M Xu, Y Liu, EB. da Silva, T Townsend, P Xiang, LQ Ma. 2019. Emerging and legacy PAHs in urban soils of four small cities: Concentrations, distribution, and sources. Science Total Environment. 685:463–470.
  • Jia, M, N Tang, Y Cao, Y Chen, YH Han, LQ. Ma. 2019. Efficient arsenate reduction by As-resistant bacterium Bacillus sp. strain PVR-YHB1-1: Characterization and genome analysis. Chemosphere 218:1061-1070.
  • Li, C, X Cui, Y Chen, C Liao, LQ. Ma. 2019. Synthetic phenolic antioxidants and their major metabolites in human fingernail. Environmental Research 169:308–314.
  • Li, H., M Li, D Zhao, J Li, S Li, P Xiang, AL. Juhasz, and LQ. Ma. 2019. Arsenic, lead, and cadmium bioaccessibility in contaminated soils: Measurements and validations. Critical Rev. Environ. Sci. Technol. doi.org/10.1080/10643389.2019.1656512
  • Li, H., M Li, D Zhao, J Li, S Li, AL. Juhasz, NT. Basta, Y Luo, and LQ. Ma. 2019 Oral bioavailability of As, Pb, and Cd in contaminated soils, dust, and foods based on animal bioassays: a review. Environ. Sci. Technol. 53, 10545−10559
  • Li, K., Z Liu, X Shi, T Wei, LQ. Ma, J Luo. 2020. Novel in situ method based on diffusive gradients in thin-films with lanthanum oxide nanoparticles for measuring As, Sb, and V and in waters. . J. Hazard. Mat 383:121196
  • Li., Y., AL. Juhasz, LQ. Ma, X. Cui. 2019. Inhalation bioaccessibility of PAHs in PM2.5: Implications for risk assessment and toxicity prediction. Sic. Total Environ. 650:56–64.
  • Li, M, P Wang, J Wang, X Chen, D Zhao, D Yin, J Luo, AL Juhasz, H Li, and LQ. Ma. 2019. Arsenic concentrations, speciation, and localization in 141 cultivated market mushrooms: implications for arsenic exposure to humans. Environ. Sci. Technol. 53:503−511.332
  • Liu, Y, P Gao, J Su, EB. da Silva, LM. de Oliveira, T Townsend, P Xiang, LQ. Ma. 2019. PAH concentrations in urban soils of two Florida cities: concentrations, distribution and sources. Chemosphere 214:220-227. 331
  • Liu, ZD, HB Li, X Fang, H Zhang, LQ. Ma, and J Luo. 2019. Investigating lead species and bioavailability in contaminated soils: coupling DGT technique with artificial gastrointestinal extraction and in vivo bioassay. Environ. Sci. Technol. 53:5717−5724.330
  • Manzoor, M., R. Abid, B. Rathinasabapathi, LM. De Oliveira, E. da Silva, F. Deng, C. Rensing, M. Arshad, I. Gul, P. Xiang, LQ. Ma. 2019. Metal tolerance of arsenic-resistant bacteria and their ability to promote plant growth of Pteris vittata in Pb-contaminated soil. Sci. Total Environ. 660: 18–24.329
  • Zhao,D., J Wang, D Yin, M Li, X Chen, AL. Juhasz, J Luo, A Navas-Acien, H Li, LQ. Ma. Arsanilic acid contributes more to total arsenic than roxarsone in chicken meat from Chinese markets. Environment Int. 130:104875
  • Zhu, X., M Li, XQ Chen, J Wang, L Li, C Tu, YM Luo, HB Li, LQ. Ma. 2019. As, Cd, and Pb relative bioavailability in contaminated soils: Coupling mouse bioassay with UBM assay. Environment Int. 130: 104875
2018(31)
  • Cao, Y; Sun, D; Chen, J; Mei, H; Ai, H; Xu, G; Chen, Y; Ma, LQ. 2018. Phosphate transporter PvPht1;2 enhances phosphorus accumulation and plant growth without impacting arsenic uptake in plants. Environ. Sci. Technol. 52:3975−3981.326
  • Chen, Y., Y Cao, B Rathinasabapathi, and LQ. Ma. 2018. Novel genes of hyperaccumulator ferns in arsenic tolerance, uptake, and metabolism: implications for crop improvement. In: Current Advances in Fern Research. Helena Fernández (ed). Springer. 361-380. 325
  • da Silva, EB., LM. de Oliveira, AC. Wilkie, Y. Liu, LQ. Ma. 2018a. Arsenic removal from As-hyperaccumulator P. vittata biomass: Coupling extraction with precipitation. Chemosphere. 193:288-294.
  • da Silva, EB., LM. de Oliveira, AC. Wilkie, Y. Liu, LQ. Ma. 2018b. Arsenic removal by As-hyperaccumulator Pteris vittata from two contaminated soils: A 5-year study. Chemosphere. 206: 736-741.
  • da Silva, EB., S. Li, LM. de Oliveira, J Gress, X. Dong, AC. Wilkie, T Townsend, LQ. Ma. 2018c. Metal leachability from coal combustion residuals under different pHs and liquid/solid ratios. J. Hazard. Mat. 341:66–74. 322
  • de Oliveira, LM, D. Suchismita, EB. da Silva, P Gao, L. Vardanyan, Y. Liu, and LQ. Ma. 2018a. Interactive effects of chromate and arsenate on their uptake and speciation in Pteris ensiformis. Plant Soil. 422:515–526.
  • de Oliveira, LM, S Das, EB. da Silva, P Gao, J Gress, Y Liu and LQ. Ma. 2018 b. Metal concentrations in traditional and herbal teas and their potential risks to human health. Science Total Environ. 633:649-657.
  • Fang, W., PN. Williams, X Fang, C. Amoah-Antwi, D. Yin, G Li, LQ. Ma, J Luo. 2018. Field-scale heterogeneity and geochemical regulation of arsenic, iron, lead, and sulfur bioavailability in paddy soil. Environ. Sci. Technol. 52, 12098−12107.
  • Gao, P., H. Li, CP. Wilson, TG. Townsend, P. Xiang, Y. Liu, LQ. Ma. 2018. Source identification of PAHs in soils based on stable carbon isotopic signatures. Critical Rev. Environ. Sci. Technol. 48: 923-948
  • Gao, P., E. da Silva, L. Hou, ND. Denslow, P. Xiang, LQ. Ma. 2018. Human exposure to polycyclic aromatic hydrocarbons: Metabolomics perspective. Environ. Int. 119: 466–477.317
  • Guan DX, YQ Li, NY Yu, GH Yu, S Wei, H Zhang, W Davison, XY Cui, LQ. Ma, J Luo. 2018. In situ measurement of perfluoroalkyl substances in aquatic systems using diffusive gradients in thin-films technique. Water Research 144:162-171.316
  • Guan DX, X. Wang, H Xu, L Chen, P Li, and LQ. Ma. 2018. Temporal and spatial distribution of Microcystis biomass and genotype in bloom areas of Lake Taihu. Chemosphere 209:730-738.315
  • Hadayat, N., L.M. De Oliveira, E. Da Silva, L. Han, M. Hussain, X. Liu, LQ. Ma. 2018. Assessment of trace metals in five most-consumed vegetables in the US: Conventional vs. organic. Environ. Pollut. 243:292-300.314
  • Han, C., PN. Williams, J Ren, Z Wang, X Fang, D Xu, X Xie, J Geng, LQ. Ma and Jun Luo. 2018. In situ sampling and speciation method for measuring dissolved phosphite at ultratrace concentrations in the natural environment. Water Research 137:281-289.313
  • He, R.W., YZ Li, P Xiang, C Li, X. Cui, and LQ. Ma. 2018. Impact of particle size on distribution and human exposure of flame retardants in indoor dust. Environ. Res. 162:166-172
  • Li, HB, MY Li, D Zhao, YG Zhu, J Li, AL. Juhasz, XY Cui, J Luo, LQ. Ma. 2018. Food influence on lead relative bioavailability in contaminated soils: Mechanisms and health implications. J. Hazard. Mat. 358:427–433.
  • Liu, Y., P Gao, J Su, EB. da Silva, LM. de Oliveira, T Townsend, P Xiang, LQ. Ma. 2018. PAHs in urban soils of two Florida cities: Background concentrations, distribution, and sources. Chemosphere 214:220-227.
  • Liu R, R He, X Cui, LQ. Ma. 2018. Impact of particle size on distribution, bioaccessibility, and cytotoxicity of polycyclic aromatic hydrocarbons in indoor dust. J. Hazard. Mat. 357:341–347.
  • Liu, X. HY Feng, JW Fu, Y. Chen, Y. Liu, and LQ. Ma. 2018. Arsenic-induced nutrient uptake in As-hyperaccumulator Pteris vittata and their potential role to enhance plant growth. Chemosphere. 198:425-431.
  • Moreira, Leo J.D., EB. da Silva, MPF. Fontes, X Liu, and LQ. Ma. 2018. Speciation, bioaccessibility and potential risk of chromium in Amazon forest soils. Environ. Pollut. 239:384-391. 307
  • Peng, A., J. Gao, Z. Chen, Y. Wang, H. Li, LQ. Ma, and C. Gu. 2018. Interactions of gaseous 2‑chlorophenol with Fe-saturated montmorillonite and their toxicity to human lung cells. Environ. Sci. Technol. 52:5208−5217.
  • Shi, X., W Fang, N Tang, PN. Williams, X Hu, Z Liu, D Yin, LQ. Ma, J Luo. 2018. In Situ Selective Measurement of SeIV in Waters and Soils: Diffusive Gradients in Thin-Films with Bi-Functionalized Silica Nanoparticles. Environ. Sci. Technol. 52, 14140−14148.
  • Wang, N, J Yua, Y Zhao, Z Chang, X Shi, H Li, LQ. Ma. 2018. Straw enhanced CO2 and CH4 but decreased N2O emissions from flooded paddy soils: Changes in microbial community compositions. Atmospheric Environment. 200:587-593.
  • Wang, Z, L Hou, Y Liu, Y Wang, and LQ. Ma. 2018. Metal contamination in a riparian wetland: Distribution, fractionation and plant uptake. Chemosphere. 200:587-593.
  • Xiang, P., Y. Jia, K. Wang, M-Y Li, Y-S Qin, R-W He, P Gao, Y Liu, X Liu, and Ma, LQ. Ma. 2018. Water extract of indoor dust induces tight junction disruption in normal human corneal epithelial cells. Environ. Pollut. 243:301-307.
  • Xiang, P., R He, R Liu, K Li, P Gao, X Cui, H Li, Y Liu, LQ. Ma. 2018. Cellular responses of normal (HL-7702) and cancerous (HepG2) hepatic cells to dust extract exposure. Chemosphere. 193:1189-1197.
  • Xiang, P., S Wang, M He, Y Han, Z Zhou, D Chen, M Li, LQ. Ma. 2018b. The in vitro and in vivo biocompatibility evaluation of electrospunre combinant spider silk protein/PCL/gelatin for small caliber vascular tissue engineering scaffolds. Colloids and Surfaces B: Biointerfaces. 163:19–28.
  • Zhang, R, C. Li, Y. Li, X. Cui, and LQ. Ma. 2018. Determination of 2,6-di-tert-butyl-hydroxytoluene and its transformation products in indoor dust and sediment by gas chromatography–mass spectrometry coupled with precolumn derivatization. Sci. Total Environ. 619–620:552–558.
  • Zhao, D., J-Y Wang, N. Tang, D-X Yin, J Luo, P Xiang, AL. Juhasz, H-B L, and LQ. Ma. 2018. Coupling bioavailability and stable isotope ratio to discern dietary and nondietary contribution of metal exposure to residents in mining-impacted areas. Environ. Int. 120:563–571.
  • Zhao, D., AL. Juhasz, J Luo, H-B Li, and LQ. Ma. 2018. Metals in paints on chopsticks: Solubilization in simulated saliva, gastric, and food solutions and implication for human health. Environ. Res. 167:299–306.
  • Zou, YT, Z. Fang, Y. Li, R. Wang, H Zhang, KC. Jones, XY Cui, XY Shi, D Yin, C Li, ZD Liu, LQ. Ma, and J Luo. 2018. Novel Method for in Situ Monitoring of Organophosphorus Flame Retardants in Waters. Anal. Chem. 90, 10016−10023
2017 (31)
  • Cao, Y. D Sun, H Ai, H Mei, X Liu, S Sun, G Xu, Y Liu, Y Chen, and LQ. Ma. 2017. Knocking out OsPT4 gene decreases arsenate uptake by rice plants and inorganic arsenic accumulation in rice grains. Environ. Sci. Technol. 51, 12131-12138.
  • Chen, Y., YH. Han, Y. Cao, YG. Zhu, B. Rathinasabapathi, and LQ. Ma. 2017. Heterologous expression of Pteris vittata arsenite antiporter PvACR3;1 reduces arsenic accumulation in plant shoots. Environ. Sci. Technol. 51, 10387−10395
  • Chen, Y., Hua, C; Jia, M; Fu, J; Liu, X; Han, YH; Liu, Y; Rathinasabapathi, B; Cao, Y, and LQ. Ma. 2017. Arsenic transport in rice and biological solutions to reduce arsenic risk from rice. Frontiers in Plant Science. doi.org/10.3389/fpls.2017.00268.
  • Das, S., de Oliveira, LM., E.B. da Silva, Y. Liu and LQ. Ma. 2017. Fluoride concentrations in traditional and herbal teas: health risk assessment. Environ. Pollut. 231:779-784
  • Das, S., de Oliveira, LM., E.B. da Silva, and LQ. Ma. 2017. Arsenate and fluoride enhanced each other’s uptake in As-sensitive plant Pteris ensiformis. Chemosphere. 180:448-454.
  • de Oliveira, LM., S. Das, J Gress, B Rathinasabapathi, Y Chen, and LQ. Ma. 2017. Arsenic uptake by lettuce from As-contaminated soil remediated with Pteris vittata and organic amendment. Chemosphere. 176:249-254.
  • 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. Mat. 330: 68–75.
  • Guan, D-X., J-L Zheng, J. Luo, H. Zhang, W. Davison, and LQ. Ma. 2017. A diffusive gradients in thin-films technique for the assessment of bisphenols desorption from soils. J. Hazard. Mat. 331: 321-328
  • Gu, X., Z. Liu, X. Wang, J. Luo, H. Zhang, W. Davison, LQ. Ma, 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. Mat. 339: 340-346.
  • Han, Y. H., J. W. Fu, P. Xiang, Y. Cao, B. Rathinasabapathi, Y. Chen, and LQ 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. Mat. 321: 146–153.
  • Han, Y. H., X. Liu, B. Rathinasabapathi, H Li, Y Chen, and LQ. Ma. 2017. Mechanisms of efficient As solubilization in soils and As accumulation by As-hyperaccumulator Pteris vittata. Environ. Pollut. 227: 569-577
  • Han, Y. H., M.R Jia, X. Liu, Y. Zhu, Y. Cao, D.L Chen, Y Chen, and LQ. Ma. 2017. Bacteria from the rhizosphere and tissues of As-hyperaccumulator Pteris vittata and their role in arsenic transformation. Chemosphere. 186:599-606.
  • Li C, Zhang R, Li Y, Zhang S, Gao P, Cui X, Ma LQ. 2017. Relative bioavailability and bioaccessibility of PCBs in soils based on a mouse model and Tenax-improved physiologically-based extraction test. Chemosphere. 186: 709-715.
  • Li, H., X. Dong, E.B. da Silva, L.M. de Oliveira, Y. Chen, LQ. Ma. 2017. Mechanisms of metal sorption by biochars: Biochar characteristics and modifications. Chemosphere. 178:466-478
  • Li, H., J Li, D Zhao, C Li, X Wang, HJ Sun, A Juhasz, LQ 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.
  • Li, K.; Sun, J; Yang, J; Roberts, S; Zhang, X-X; Cui, X; Wei, S; Ma, LQ. 2017. Molecular mechanisms of perfluorooctanoate-induced hepatocyte apoptosis in mice using proteomic techniques. Environ. Sci. Technol. 51:11380−11389.
  • 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. Environ. Int. 99: 43–54.
  • Li, SW, HJ Sun, G Wang, Xin-Yi Cui, A. Juhasz, HB Li and LQ. Ma. 2017. Lead relative bioavailability in soils based on different endpoints of a mouse model. J. Hazard Mat. 326:94–100
  • Li, SW, 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 Mat. 339: 256–263.
  • Liu, X., JW. Fu, N. Tang, E. Da Silva, B.L. Turner, Y. Cao, Y. Chen, and L. Q. Ma. 2017. Phytate induced arsenic uptake and plant growth in arsenic-hyperaccumulator Pteris vittata. Environ. Pollut. 226:212-218.
  • Liu, X., JW. Fu, E. Da Silva, XX. 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.
  • Sun, HJ, Li SW, Li C, Wang WQ, Li HB, Ma LQ. 2017. Thyrotoxicity of arsenate and arsenite on juvenile mice at organism, subcellular, and gene levels under low exposure. Chemosphere. 186:580-587.
  • Wang, N., ZZ. Chang*, XX. Xue, JG. Yu, XX., Shi, LQ. Ma, and HB. Li. 2017. Biochar decreases nitrogen oxide and enhances methane emissions via altering microbial community composition of anaerobic paddy soil. Sci. Total Environ. 581–582: 689–696
  • Xiang, P., R-Y Liu, H-J Sun, Y-W Yang, X-Y Cui, LQ. Ma. 2017. Effects of novel brominated flame retardant TBPH and its metabolite TBMEHP to human vascular endothelial cells: implication for human health risks. Environ. Res. 156:834–842.
  • Xiang, P., R-Y Liu, C. Li, P. Gao, X-Y Cui, LQ. Ma. 2017.Effects of organophosphorus flame retardant TDCPP on normal human corneal epithelial cells: Implications for human health. Environ. Pullut. 230:22-30.
  • Yin, D., X Wang, B Peng, C Tan, LQ. Ma. 2017. Effect of biochar and Fe-biochar on Cd and As mobility and transfer in soil-rice system. Chemosphere 186:928-937
  • Xu, C, W. Yang, L Zhu, AL. Juhasz, LQ. Ma, J Wang, A Lin. 2017. Remediation of polluted soil in China: policy and technology bottlenecks. Environ. Sci. Technol. 51:14027−14029.
  • Zhang, S., C. Li, Y. Li, R. Zhang, P. Gao, X-Y Cui, LQ. Ma. 2017. Bioaccessibility of PAHs in contaminated soils: Comparison of five in vitro methods with Tenax as a sorption sink. Sci. Total Environ. 601–602:968–974
  • Zhang, S., PN. Williams, C-Y Zhou, LQ. Ma, 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
  • Zhao, D. R-Y Liu, P Xiang, AL. Juhasz, L Huang, J Luo, HB Li, and LQ. 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
  • Zhao, D., AL. Juhasz, J Luo, L Huang, X-S Luo, HB Li, and LQ. Ma. 2017. Mineral dietary supplement to decrease cadmium relative bioavailability in rice based on a mouse bioassay. Environ. Sci. Technol. 51, 12123-12130

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