Your search keyword '"Jusko, T.A. (Todd A)"' showing total 4 results

1. Organophosphate pesticide metabolite concentrations in urine during pregnancy and offspring attention-deficit hyperactivity disorder and autistic traits

Author

Dries, M.A. (Michiel) van den, Guxens Junyent, M. (Mònica), Pronk, A. (Apollo), Spaan, S. (Suzanne), El Marroun, H. (Hanan), Jusko, T.A. (Todd A), Longnecker, M.P. (Matthew), Ferguson, K. (Kelly), Tiemeier, H.W. (Henning), Dries, M.A. (Michiel) van den, Guxens Junyent, M. (Mònica), Pronk, A. (Apollo), Spaan, S. (Suzanne), El Marroun, H. (Hanan), Jusko, T.A. (Todd A), Longnecker, M.P. (Matthew), Ferguson, K. (Kelly), and Tiemeier, H.W. (Henning)

Abstract

Background: Prenatal exposure to organophosphate (OP) pesticides has been associated with altered neuronal cell development and behavioral changes in animal offspring. However, the few studies investigating the association between prenatal OP pesticide exposure and neurodevelopmental outcomes such as Attention-Deficit Hyperactivity Disorder (ADHD) and autistic traits in children produced mixed findings. Objective: The objective of the present study was to examine whether maternal urinary concentrations of OP pesticide metabolites are associated with ADHD and autistic traits in children participating in the Generation R Study, a population-based birth cohort from Rotterdam, the Netherlands. Method: Maternal concentrations of 6 dialkylphosphates (DAPs) were measured using gas chromatography coupled with tandem mass spectrometry in urine samples collected at <18 weeks, 18‐25 weeks, and > 25 weeks of gestation in 784 mother-child pairs. DAP metabolite concentrations were expressed as molar concentrations divided by creatinine levels and log10 transformed. ADHD traits were measured at ages 3, 6, and 10 years using the Child Behavior Checklist (CBCL) (n = 781) and autistic traits were measured at age 6 years using the Social Responsiveness Scale (SRS) (n = 622). First, regression models were fit for the averaged prenatal exposure across pregnancy. Second, we investigated associations for each collection phase separately, and applied a mutually adjusted model in which the effect of prenatal DAP concentrations from each time period on ADHD and autistic traits were jointly estimated. All associations were adjusted for relevant confounders. Results: Median DAP metabolite concentration was 309 nmol/g creatinine at <18 weeks, 316 nmol/g creatinine at 18–25 weeks, and 308 nmol/g creatinine at >25 weeks of gestation. Overall, DAP metabolite concentrations were not associated with ADHD traits. For instance, a log10 increase in averaged total DAP concentrations across gestation was

Published

2019

2. Gestational weight gain charts for different body mass index groups for women in Europe, North America, and Oceania

Author

Santos, S. (Susana), Eekhout, I. (Iris), Voerman, E. (Ellis), Gaillard, R. (Romy), Barros, A.I. (Ana), Charles, M.A., Chatzi, L. (Leda), Chevrier, C. (Cécile), Chrousos, G.P. (George P.), Corpeleijn, W.E. (Willemijn), Costet, N. (Nathalie), Crozier, S. (Sarah), Doyon, M. (Myriam), Eggesbø, M. (Merete), Fantini, M.P. (Maria), Farchi, S. (Sara), Forastiere, F. (Francesco), Gagliardi, L. (Luigi), Georgiu, V. (Vagelis), Godfrey, K.M. (Keith M.), Gori, D. (Davide), Grote, V. (Veit), Hanke, W. (Wojciech), Hertz-Picciotto, I. (Irva), Heude, B. (Barbara), Hivert, M.-F. (Marie-France), Hryhorczuk, D.O. (Daniel), Huang, R.-C. (Rae-Chi), Inskip, H.M. (Hazel), Jusko, T.A. (Todd A), Karvonen, A.M. (Anne M.), Koletzko, B. (Berthold), Küpers, A.M. (Marlijn), Lagström, H. (Hanna), Lawlor, D.A. (Debbie A.), Lehmann, I. (Irina), Lopez-Espinosa, M.-J. (Maria-Jose), Magnus, P. (Per), Majewska, R. (Renata), Mäkelä, J. (Johanna), Manios, Y., McDonald, S.W. (Sheila W.), Mommers, M. (Monique), Morgen, C.S. (Camilla S.), Moschonis, G., Murinova, L.P. (Lubica Palkovicova), Newnham, J.P. (John), Nohr, C. (Christian), Andersen, A-M.N. (Anne-Marie Nybo), Oken, E. (Emily), Oostvogels, A.J.J.M. (Adriëtte J. J. M.), Pac, A. (Agnieszka), Papadopoulou, E. (Eleni), Pekkanen, J. (Juha), Pizzi, C. (Costanza), Polanska, K. (Kinga), Porta, D. (Daniela), Richiardi, L. (Lorenzo), Rifas-Shiman, S.L. (Sheryl), Roeleveld, N. (Nel), Santa-Marina, L. (Loreto), Santos, A.C. (Ana Cristina), Smit, H.A. (Henriëtte), Sørensen, T.I.A. (Thorkild), Standl, M. (Marie), Stanislawski, M. (Maggie), Stoltenberg, C. (Camilla), Thiering, E. (Elisabeth), Thijs, C. (Carel), Torrent, M. (Maties), Tough, S.C. (Suzanne C.), Trnovec, T. (Tomáš), Van Gelder, M.M.H.J. (Marleen M. H. J.), Rossem, L. (Lenie) van, Berg, A. (Andrea) von, Vrijheid, M. (Martine), Vrijkotte, T.G.M. (Tanja), Zvinchuk, O. (Oleksandr), Buuren, S. (Stef) van, Jaddoe, V.W.V. (Vincent), Santos, S. (Susana), Eekhout, I. (Iris), Voerman, E. (Ellis), Gaillard, R. (Romy), Barros, A.I. (Ana), Charles, M.A., Chatzi, L. (Leda), Chevrier, C. (Cécile), Chrousos, G.P. (George P.), Corpeleijn, W.E. (Willemijn), Costet, N. (Nathalie), Crozier, S. (Sarah), Doyon, M. (Myriam), Eggesbø, M. (Merete), Fantini, M.P. (Maria), Farchi, S. (Sara), Forastiere, F. (Francesco), Gagliardi, L. (Luigi), Georgiu, V. (Vagelis), Godfrey, K.M. (Keith M.), Gori, D. (Davide), Grote, V. (Veit), Hanke, W. (Wojciech), Hertz-Picciotto, I. (Irva), Heude, B. (Barbara), Hivert, M.-F. (Marie-France), Hryhorczuk, D.O. (Daniel), Huang, R.-C. (Rae-Chi), Inskip, H.M. (Hazel), Jusko, T.A. (Todd A), Karvonen, A.M. (Anne M.), Koletzko, B. (Berthold), Küpers, A.M. (Marlijn), Lagström, H. (Hanna), Lawlor, D.A. (Debbie A.), Lehmann, I. (Irina), Lopez-Espinosa, M.-J. (Maria-Jose), Magnus, P. (Per), Majewska, R. (Renata), Mäkelä, J. (Johanna), Manios, Y., McDonald, S.W. (Sheila W.), Mommers, M. (Monique), Morgen, C.S. (Camilla S.), Moschonis, G., Murinova, L.P. (Lubica Palkovicova), Newnham, J.P. (John), Nohr, C. (Christian), Andersen, A-M.N. (Anne-Marie Nybo), Oken, E. (Emily), Oostvogels, A.J.J.M. (Adriëtte J. J. M.), Pac, A. (Agnieszka), Papadopoulou, E. (Eleni), Pekkanen, J. (Juha), Pizzi, C. (Costanza), Polanska, K. (Kinga), Porta, D. (Daniela), Richiardi, L. (Lorenzo), Rifas-Shiman, S.L. (Sheryl), Roeleveld, N. (Nel), Santa-Marina, L. (Loreto), Santos, A.C. (Ana Cristina), Smit, H.A. (Henriëtte), Sørensen, T.I.A. (Thorkild), Standl, M. (Marie), Stanislawski, M. (Maggie), Stoltenberg, C. (Camilla), Thiering, E. (Elisabeth), Thijs, C. (Carel), Torrent, M. (Maties), Tough, S.C. (Suzanne C.), Trnovec, T. (Tomáš), Van Gelder, M.M.H.J. (Marleen M. H. J.), Rossem, L. (Lenie) van, Berg, A. (Andrea) von, Vrijheid, M. (Martine), Vrijkotte, T.G.M. (Tanja), Zvinchuk, O. (Oleksandr), Buuren, S. (Stef) van, and Jaddoe, V.W.V. (Vincent)

Abstract

Background: Gestational weight gain differs according to pre-pregnancy body mass index and is related to the risks of adverse maternal and child health outcomes. Gestational weight gain charts for women in different pre-pregnancy body mass index groups enable identification of women and offspring at risk for adverse health outcomes. We aimed to construct gestational weight gain reference charts for underweight, normal weight, overweight, and grades 1, 2 and 3 obese women and to compare these charts with those obtained in women with uncomplicated term pregnancies. Methods: We used individual participant data from 218,216 pregnant women participating in 33 cohorts from Europe, North America, and Oceania. Of these women, 9065 (4.2%), 148,697 (68.1%), 42,678 (19.6%), 13,084 (6.0%), 3597 (1.6%), and 1095 (0.5%) were underweight, normal weight, overweight, and grades 1, 2, and 3 obese women, respectively. A total of 138, 517 women from 26 cohorts had pregnancies with no hypertensive or diabetic disorders and with term deliveries of appropriate for gestational age at birth infants. Gestational weight gain charts for underweight, normal weight, overweight, and grade 1, 2, and 3 obese women were derived by the Box-Cox t method using the generalized additive model for location, scale, and shape. Results: We observed that gestational weight gain strongly differed per maternal pre-pregnancy body mass index group. The median (interquartile range) gestational weight gain at 40 weeks was 14.2 kg (11.4-17.4) for underweight women, 14.5 kg (11.5-17.7) for normal weight women, 13.9 kg (10.1-17.9) for overweight women, and 11.2 kg (7.0-15.7), 8.7 kg (4.3-13.4) and 6.3 kg (1.9-11.1) for grades 1, 2, and 3 obese women, respectively. The rate of weight gain was lower in the first half than in the second half of pregnancy. No differences in the patterns of weight gain were observed between cohorts or countries. Similar weight gain patterns were observed in mothers without pregnancy compli

Published

2018

3. Determinants of organophosphate pesticide exposure in pregnant women: A population-based cohort study in the Netherlands

Author

van den Dries, M.A. (Michiel A.), Pronk, A. (Apollo), Guxens Junyent, M. (Mònica), Spaan, S. (Suzanne), Voortman, R.G. (Trudy), Jaddoe, V.W.V. (Vincent), Jusko, T.A. (Todd A), Longnecker, M.P. (Matthew), Tiemeier, H.W. (Henning), van den Dries, M.A. (Michiel A.), Pronk, A. (Apollo), Guxens Junyent, M. (Mònica), Spaan, S. (Suzanne), Voortman, R.G. (Trudy), Jaddoe, V.W.V. (Vincent), Jusko, T.A. (Todd A), Longnecker, M.P. (Matthew), and Tiemeier, H.W. (Henning)

Abstract

Background: In the Netherlands organophosphate (OP) pesticides are frequently used for pest control in agricultural settings. Despite concerns about the potential health impacts of low-level OP pesticides exposure, particularly in vulnerable populations, the primary sources of exposure remain unclear. The present study was designed to investigate the levels of DAP metabolites concentrations across pregnancy and to examine various determinants of DAP metabolite concentrations among an urban population of women in the Netherlands. Method: Urinary concentrations of six dialkyl phosphate (DAP) metabolites, the main urinary metabolites of OP pesticides, were determined at <18, 18-25, and >25 weeks of pregnancy in 784 pregnant women participating in the Generation R Study (between 2004 and 2006), a large population-based birth cohort in Rotterdam, the Netherlands. Questionnaires administered prenatally assessed demographic and lifestyle characteristics and maternal diet. Linear mixed models, with adjustment for relevant covariates, were used to estimate associations between the potential exposure determinants and DAP metabolite concentrations expressed as molar concentrations divided by creatinine levels. Results: The median DAP metabolite concentration was 311 nmol/g creatinine for the first trimester, 317 nmol/g creatinine for the second trimester, and 310 nmol/g creatinine for the third trimester. Higher maternal age, married/living with a partner, underweight or normal weight (BMI of <18.5 and 18.5-<25), high education, high income, and non-smoking were associated with higher DAP metabolite concentrations, and DAP metabolite concentrations tended to be higher during the summer. Furthermore, fruit intake was associated with increased DAP metabolite concentrations. Each 100 g/d difference in fruit consumption was associated with a 7% higher total DAP metabolite concentration across pregnancy. Other food groups were not associated with higher DAP metabolite concentration

Published

2018

4. Reliability of concentrations of organophosphate pesticide metabolites in serial urine specimens from pregnancy in the Generation R Study

Author

Spaan, S. (Suzanne), Pronk, A. (Anjoeka), Koch, H.M. (Holger M.), Jusko, T.A. (Todd A), Jaddoe, V.W.V. (Vincent), Shaw, P.A. (Pamela A.), Tiemeier, H.W. (Henning), Hofman, A. (Albert), Pierik, F.H. (Frank), Longnecker, M.P. (Matthew), Spaan, S. (Suzanne), Pronk, A. (Anjoeka), Koch, H.M. (Holger M.), Jusko, T.A. (Todd A), Jaddoe, V.W.V. (Vincent), Shaw, P.A. (Pamela A.), Tiemeier, H.W. (Henning), Hofman, A. (Albert), Pierik, F.H. (Frank), and Longnecker, M.P. (Matthew)

Abstract

The widespread use of organophosphate (OP) pesticides has resulted in ubiquitous exposure in humans, primarily through their diet. Exposure to OP pesticides may have adverse health effects, including neurobehavioral deficits in children. The optimal design of new studies requires data on the reliability of urinary measures of exposure. In the present study, urinary concentrations of six dialkyl phosphate (DAP) metabolites, the main urinary metabolites of OP pesticides, were determined in 120 pregnant women participating in the Generation R Study in Rotterdam. Intra-class correlation coefficients (ICCs) across serial urine specimens taken at <18, 18-25, and >25 weeks of pregnancy were determined to assess reliability. Geometric mean total DAP metabolite concentrations were 229 (GSD 2.2), 240 (GSD 2.1), and 224 (GSD 2.2) nmol/g creatinine across the three periods of gestation. Metabolite concentrations from the serial urine specimens in general correlated moderately. The ICCs for the six DAP metabolites ranged from 0.14 to 0.38 (0.30 for total DAPs), indicating weak to moderate reliability. Although the DAP metabolite levels observed in this study are slightly higher and slightly more correlated than in previous studies, the low to moderate reliability indicates a high degree of within-person variability, which presents challenges for designing well-powered epidemiological studies.

Published

2015