Literature DB >> 27168393

Comparison of stationary and personal air sampling with an air dispersion model for children's ambient exposure to manganese.

Florence Fulk1, Erin N Haynes2, Timothy J Hilbert2, David Brown3, Dan Petersen4, Tiina Reponen2.   

Abstract

Manganese (Mn) is ubiquitous in the environment and essential for normal growth and development, yet excessive exposure can lead to impairments in neurological function. This study modeled ambient Mn concentrations as an alternative to stationary and personal air sampling to assess exposure for children enrolled in the Communities Actively Researching Exposure Study in Marietta, OH. Ambient air Mn concentration values were modeled using US Environmental Protection Agency's Air Dispersion Model AERMOD based on emissions from the ferromanganese refinery located in Marietta. Modeled Mn concentrations were compared with Mn concentrations from a nearby stationary air monitor. The Index of Agreement for modeled versus monitored data was 0.34 (48 h levels) and 0.79 (monthly levels). Fractional bias was 0.026 for 48 h levels and -0.019 for monthly levels. The ratio of modeled ambient air Mn to measured ambient air Mn at the annual time scale was 0.94. Modeled values were also time matched to personal air samples for 19 children. The modeled values explained a greater degree of variability in personal exposures compared with time-weighted distance from the emission source. Based on these results modeled Mn concentrations provided a suitable approach for assessing airborne Mn exposure in this cohort.

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Year:  2016        PMID: 27168393     DOI: 10.1038/jes.2016.30

Source DB:  PubMed          Journal:  J Expo Sci Environ Epidemiol        ISSN: 1559-0631            Impact factor:   5.563


  31 in total

1.  Modeling and estimating manganese concentrations in rural households in the mining district of Molango, Mexico.

Authors:  Marlene Cortez-Lugo; Sandra Rodríguez-Dozal; Irma Rosas-Pérez; Urinda Alamo-Hernández; Horacio Riojas-Rodríguez
Journal:  Environ Monit Assess       Date:  2015-11-14       Impact factor: 2.513

2.  Comparison of the industrial source complex and AERMOD dispersion models: case study for human health risk assessment.

Authors:  Keith C Silverman; Joan G Tell; Edward V Sargent; Zeyuan Qiu
Journal:  J Air Waste Manag Assoc       Date:  2007-12       Impact factor: 2.235

3.  Lead-contaminated house dust and urban children's blood lead levels.

Authors:  B P Lanphear; M Weitzman; N L Winter; S Eberly; B Yakir; M Tanner; M Emond; T D Matte
Journal:  Am J Public Health       Date:  1996-10       Impact factor: 9.308

4.  House and hand dust as a potential source of childhood lead exposure.

Authors:  J W Sayre; E Charney; J Vostal; I B Pless
Journal:  Am J Dis Child       Date:  1974-02

5.  Assessment of personal exposure to manganese in children living near a ferromanganese refinery.

Authors:  Erin N Haynes; Pat Ryan; Aimin Chen; David Brown; Sandy Roda; Pierce Kuhnell; Dawn Wittberg; Matthew Terrell; Tiina Reponen
Journal:  Sci Total Environ       Date:  2012-05-01       Impact factor: 7.963

6.  Using soil records with atmospheric dispersion modeling to investigate the effects of clean air regulations on 60 years of manganese deposition in Marietta, Ohio (USA).

Authors:  Megan R Carter; Brian J Gaudet; David R Stauffer; Timothy S White; Susan L Brantley
Journal:  Sci Total Environ       Date:  2015-02-16       Impact factor: 7.963

7.  Metal sources and exposures in the homes of young children living near a mining-impacted Superfund site.

Authors:  Ami R Zota; Laurel A Schaider; Adrienne S Ettinger; Robert O Wright; James P Shine; John D Spengler
Journal:  J Expo Sci Environ Epidemiol       Date:  2011-05-18       Impact factor: 5.563

Review 8.  Neuropsychological testing for the assessment of manganese neurotoxicity: a review and a proposal.

Authors:  Silvia Zoni; Elisa Albini; Roberto Lucchini
Journal:  Am J Ind Med       Date:  2007-11       Impact factor: 2.214

9.  Elevated airborne manganese and low executive function in school-aged children in Brazil.

Authors:  Chrissie F Carvalho; José A Menezes-Filho; Vitor P de Matos; Jonatas Reis Bessa; Juliana Coelho-Santos; Gustavo F S Viana; Nayara Argollo; Neander Abreu
Journal:  Neurotoxicology       Date:  2013-12-03       Impact factor: 4.294

Review 10.  Manganese exposure and the neuropsychological effect on children and adolescents: a review.

Authors:  José A Menezes-Filho; Maryse Bouchard; Paula de N Sarcinelli; Josino C Moreira
Journal:  Rev Panam Salud Publica       Date:  2009-12
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  3 in total

1.  Pathways of inhalation exposure to manganese in children living near a ferromanganese refinery: A structural equation modeling approach.

Authors:  Florence Fulk; Paul Succop; Timothy J Hilbert; Caroline Beidler; David Brown; Tiina Reponen; Erin N Haynes
Journal:  Sci Total Environ       Date:  2016-11-17       Impact factor: 7.963

Review 2.  Manganese and Developmental Neurotoxicity.

Authors:  Roberto Lucchini; Donatella Placidi; Giuseppa Cagna; Chiara Fedrighi; Manuela Oppini; Marco Peli; Silvia Zoni
Journal:  Adv Neurobiol       Date:  2017

3.  Short- and long-term exposure to trace metal(loid)s from the production of ferromanganese alloys by personal sampling and biomarkers.

Authors:  B Markiv; L Ruiz-Azcona; A Expósito; M Santibáñez; I Fernández-Olmo
Journal:  Environ Geochem Health       Date:  2022-02-22       Impact factor: 4.609
  3 in total

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