Individual and mixtures of metal exposures in associations with biomarkers of oxidative stress and global DNA methylation among pregnant women.
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Chong Liu | Qiong Luo | Jia-Yue Zeng | Tian Shi | Yu Miao | Pan-Pan Chen | Min Zhang | Y. Deng | Feipeng Cui | Ting-Ting Lu | Wen-Ding Li | Xue-Dan Xu | Qiang Zeng | Yan-Ling Deng
[1] Linsheng Yang,et al. Association of selenium, arsenic, and other trace elements in drinking water and urine in residents of the plateau region in China , 2021, Environmental Science and Pollution Research.
[2] Wenyue Zhang,et al. Selenium deficiency induced apoptosis via mitochondrial pathway caused by Oxidative Stress in porcine gastric tissues. , 2021, Research in veterinary science.
[3] Yunyun Liu,et al. Association between maternal urinary selenium during pregnancy and newborn telomere length: results from a birth cohort study , 2021, European Journal of Clinical Nutrition.
[4] Yingying Zheng,et al. Calcium overload and reactive oxygen species accumulation induced by selenium deficiency promote autophagy in swine small intestine , 2021, Animal nutrition.
[5] M. Casas,et al. Exposure to metals and metalloids among pregnant women from Spain: Levels and associated factors. , 2021, Chemosphere.
[6] J. Meeker,et al. Cross-Sectional Estimation of Endogenous Biomarker Associations with Prenatal Phenols, Phthalates, Metals, and Polycyclic Aromatic Hydrocarbons in Single-Pollutant and Mixtures Analysis Approaches , 2021, Environmental health perspectives.
[7] S. Biswal,et al. Prenatal Environmental Metal Exposure and Preterm Birth: A Scoping Review , 2021, International journal of environmental research and public health.
[8] S. Leng,et al. Ambient particulate matter compositions and increased oxidative stress: Exposure-response analysis among high-level exposed population. , 2020, Environment international.
[9] A. Alshawabkeh,et al. Maternal Urinary Metal and Metalloid Concentrations in Association with Oxidative Stress Biomarkers , 2020, Antioxidants.
[10] Caiying Zhang,et al. Inhibition of autophagy aggravates molybdenum-induced mitochondrial dysfunction by aggravating oxidative stress in duck renal tubular epithelial cells. , 2020, Ecotoxicology and environmental safety.
[11] J. Meeker,et al. Prenatal Metal Mixtures and Birth Weight for Gestational Age in a Predominately Lower-Income Hispanic Pregnancy Cohort in Los Angeles , 2020, Environmental health perspectives.
[12] Preeti Singh,et al. Evaluation of oxidative stress and pro-inflammatory cytokines in occupationally exposed cadmium workers. , 2020, Work.
[13] S. Kwiatkowski,et al. The Role of Fe, Zn, and Cu in Pregnancy , 2020, Biomolecules.
[14] A. Alshawabkeh,et al. Maternal blood metal and metalloid concentrations in association with birth outcomes in Northern Puerto Rico. , 2020, Environment international.
[15] T. Reponen,et al. Birth outcomes associated with maternal exposure to metals from informal electronic waste recycling in Guiyu, China. , 2020, Environment international.
[16] Yi-Xin Wang,et al. Blood and urinary biomarkers of prenatal exposure to disinfection byproducts and oxidative stress: A repeated measurement analysis. , 2020, Environment international.
[17] J. Meeker,et al. Exposure to 17 trace metals in pregnancy and associations with urinary oxidative stress biomarkers. , 2019, Environmental research.
[18] M. Holland,et al. DNA methylation at the crossroads of gene and environment interactions , 2019, Essays in biochemistry.
[19] Suli Huang,et al. Heavy metal exposure, oxidative stress and semen quality: Exploring associations and mediation effects in reproductive-aged men. , 2019, Chemosphere.
[20] I. Omotosho. Oxidative Stress Indices as Markers of Lead and Cadmium Exposure Toxicity in Auto Technicians in Ibadan, Nigeria , 2019, Oxidative medicine and cellular longevity.
[21] M. Ehrlich. DNA hypermethylation in disease: mechanisms and clinical relevance , 2019, Epigenetics.
[22] Ki‐Hyun Kim,et al. Heavy metals in food crops: Health risks, fate, mechanisms, and management. , 2019, Environment international.
[23] W. Xia,et al. Urinary concentrations of environmental metals and associating factors in pregnant women , 2019, Environmental Science and Pollution Research.
[24] X. Miao,et al. Urinary levels of bisphenol A, F and S and markers of oxidative stress among healthy adult men: Variability and association analysis. , 2019, Environment international.
[25] J. Redón,et al. Urinary metals and metal mixtures and oxidative stress biomarkers in an adult population from Spain: The Hortega Study. , 2019, Environment international.
[26] F. Tao,et al. Prenatal thallium exposure and poor growth in early childhood: A prospective birth cohort study. , 2019, Environment international.
[27] Zeina Salloum,et al. Effects of cobalt and chromium ions on oxidative stress and energy metabolism in macrophages in vitro , 2018, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.
[28] Elena I. Queirolo,et al. Multiple‐metal exposure, diet, and oxidative stress in Uruguayan school children , 2018, Environmental research.
[29] Jennifer F. Bobb,et al. Statistical software for analyzing the health effects of multiple concurrent exposures via Bayesian kernel machine regression , 2018, Environmental Health.
[30] L. Hudson,et al. Metal exposure and oxidative stress markers in pregnant Navajo Birth Cohort Study participants , 2018, Free radical biology & medicine.
[31] B. Eskenazi,et al. Association between prenatal exposure to multiple insecticides and child body weight and body composition in the VHEMBE South African birth cohort. , 2018, Environment international.
[32] C. Watanabe,et al. Prenatal Heavy Metal Exposure and Adverse Birth Outcomes in Myanmar: A Birth-Cohort Study , 2017, International journal of environmental research and public health.
[33] F. Ping,et al. DNA Methylation and Birth Weight: a Genome-wide Analysis. , 2017, Biomedical and environmental sciences : BES.
[34] A. Baccarelli,et al. Prenatal Exposure to Mercury: Associations with Global DNA Methylation and Hydroxymethylation in Cord Blood and in Childhood , 2017, Environmental health perspectives.
[35] A. Kasperczyk,et al. Oxidative DNA damage and oxidative stress in lead-exposed workers , 2017, Human & experimental toxicology.
[36] C. Lu,et al. Prenatal Nonylphenol and Bisphenol A Exposures and Inflammation Are Determinants of Oxidative/Nitrative Stress: A Taiwanese Cohort Study. , 2017, Environmental science & technology.
[37] Yi-Xin Wang,et al. Prenatal exposure to drinking water disinfection by-products and DNA methylation in cord blood. , 2017, The Science of the total environment.
[38] T. Bianco-Miotto,et al. Association between Maternal Zinc Status, Dietary Zinc Intake and Pregnancy Complications: A Systematic Review , 2016, Nutrients.
[39] N. Zeghal,et al. Barium chloride induces redox status unbalance, upregulates cytokine genes expression and confers hepatotoxicity in rats—alleviation by pomegranate peel , 2016, Environmental Science and Pollution Research.
[40] Yachao Wang,et al. Excessive Selenium Supplementation Induced Oxidative Stress and Endoplasmic Reticulum Stress in Chicken Spleen , 2016, Biological Trace Element Research.
[41] S. Arifeen,et al. Prenatal lead exposure is associated with decreased cord blood DNA methylation of the glycoprotein VI gene involved in platelet activation and thrombus formation , 2015, Environmental epigenetics.
[42] Yi-Xin Wang,et al. Variability of Metal Levels in Spot, First Morning, and 24-Hour Urine Samples over a 3-Month Period in Healthy Adult Chinese Men , 2015, Environmental health perspectives.
[43] Fan Wang,et al. Blood Biomarkers of Late Pregnancy Exposure to Trihalomethanes in Drinking Water and Fetal Growth Measures and Gestational Age in a Chinese Cohort , 2015, Environmental health perspectives.
[44] F. Perera,et al. Life-Long Implications of Developmental Exposure to Environmental Stressors: New Perspectives. , 2015, Endocrinology.
[45] Ping Liu,et al. Mitochondrial oxidative stress-induced hepatocyte apoptosis reflects increased molybdenum intake in caprine , 2015, Biological Trace Element Research.
[46] B. Coull,et al. Bayesian kernel machine regression for estimating the health effects of multi-pollutant mixtures. , 2015, Biostatistics.
[47] Tangchun Wu,et al. The effects of heavy metals and their interactions with polycyclic aromatic hydrocarbons on the oxidative stress among coke-oven workers. , 2015, Environmental research.
[48] M. Vinceti,et al. Selenium and Human Health: Witnessing a Copernican Revolution? , 2015, Journal of environmental science and health. Part C, Environmental carcinogenesis & ecotoxicology reviews.
[49] P. Jin,et al. DNA methylation and hydroxymethylation in stem cells , 2015, Cell biochemistry and function.
[50] H. Sies,et al. Oxidative stress: a concept in redox biology and medicine , 2015, Redox biology.
[51] H. Kan,et al. Urinary Metals and Heart Rate Variability: A Cross-Sectional Study of Urban Adults in Wuhan, China , 2014, Environmental health perspectives.
[52] E. Guallar,et al. Plasma selenium levels and oxidative stress biomarkers: a gene-environment interaction population-based study. , 2014, Free radical biology & medicine.
[53] F. Tang,et al. The DNA methylation landscape of human early embryos , 2014, Nature.
[54] A. Bitto,et al. Oxidative stress and DNA repair and detoxification gene expression in adolescents exposed to heavy metals living in the Milazzo-Valle del Mela area (Sicily, Italy) , 2014, Redox biology.
[55] E. Guallar,et al. Association of Global DNA Methylation and Global DNA Hydroxymethylation with Metals and Other Exposures in Human Blood DNA Samples , 2014, Environmental health perspectives.
[56] M. Casas,et al. Assessment of exposure to trace metals in a cohort of pregnant women from an urban center by urine analysis in the first and third trimesters of pregnancy , 2014, Environmental Science and Pollution Research.
[57] F. Wright,et al. Cadmium exposure and the epigenome: Exposure-associated patterns of DNA methylation in leukocytes from mother-baby pairs , 2014, Epigenetics.
[58] G. Shaw,et al. Could genetic polymorphisms related to oxidative stress modulate effects of heavy metals for risk of human preterm birth? , 2013, Reproductive toxicology.
[59] M. Boyce,et al. Maternal exposure to metals--concentrations and predictors of exposure. , 2013, Environmental research.
[60] Ivan Spasojevic,et al. Urinary biomarkers of oxidative status. , 2012, Clinica chimica acta; international journal of clinical chemistry.
[61] A. Baccarelli,et al. Associations of LINE-1 DNA Methylation with Preterm Birth in a Prospective Cohort Study. , 2012, Journal of developmental origins of health and disease.
[62] M. Ruchirawat,et al. Effects of arsenic exposure on DNA methylation in cord blood samples from newborn babies and in a human lymphoblast cell line , 2012, Environmental Health.
[63] A. Baccarelli,et al. Prenatal Arsenic Exposure and DNA Methylation in Maternal and Umbilical Cord Blood Leukocytes , 2012, Environmental health perspectives.
[64] Nathan Pike,et al. Using false discovery rates for multiple comparisons in ecology and evolution , 2011 .
[65] M. Valko,et al. Advances in metal-induced oxidative stress and human disease. , 2011, Toxicology.
[66] L. Kooistra,et al. Maternal selenium status during early gestation and risk for preterm birth , 2011, Canadian Medical Association Journal.
[67] T. Eeva,et al. Metal-related oxidative stress in birds. , 2010, Environmental pollution.
[68] M. Pavlica,et al. Thallium Toxicity in Humans , 2010, Arhiv za higijenu rada i toksikologiju.
[69] Rosalind J Wright,et al. Biomarkers of Lead Exposure and DNA Methylation within Retrotransposons , 2010, Environmental health perspectives.
[70] L. Hou,et al. Changes in DNA methylation patterns in subjects exposed to low-dose benzene. , 2007, Cancer research.
[71] M. Ahamed,et al. Delta-aminolevulinic acid dehydratase inhibition and oxidative stress in relation to blood lead among urban adolescents , 2006, Human & experimental toxicology.
[72] W. Dean,et al. DNA methylation in mammalian development and disease. , 2005, Birth defects research. Part C, Embryo today : reviews.
[73] M. Cronin,et al. Metals, toxicity and oxidative stress. , 2005, Current medicinal chemistry.
[74] Muralidhara,et al. Nickel-induced oxidative stress in testis of mice: evidence of DNA damage and genotoxic effects. , 2004, Journal of andrology.
[75] Samuel P. Caudill,et al. Urinary Creatinine Concentrations in the U.S. Population: Implications for Urinary Biologic Monitoring Measurements , 2004, Environmental health perspectives.
[76] H. Gurer-Orhan,et al. Correlation between clinical indicators of lead poisoning and oxidative stress parameters in controls and lead-exposed workers. , 2004, Toxicology.
[77] Lars Jarup,et al. Hazards of heavy metal contamination. , 2003 .
[78] F. Caradonna,et al. Arsenic-induced DNA hypomethylation affects chromosomal instability in mammalian cells. , 2003, Carcinogenesis.
[79] M. Waalkes,et al. Effects of cadmium on DNA-(Cytosine-5) methyltransferase activity and DNA methylation status during cadmium-induced cellular transformation. , 2003, Experimental cell research.
[80] Y. W. Lee,et al. Effects of nickel on DNA methyltransferase activity and genomic DNA methylation levels. , 1998, Mutation research.
[81] X. Shi,et al. Vanadium(IV)-mediated free radical generation and related 2'-deoxyguanosine hydroxylation and DNA damage. , 1996, Toxicology.
[82] S. Hernberg,et al. Parameters indicative of absorption and biological effect in new lead exposure: a prospective study , 1973, British journal of industrial medicine.
[83] P. Tchounwou,et al. Heavy metal toxicity and the environment. , 2012, Experientia supplementum.