%0 Journal Article %J R Soc Open Sci %D 2019 %T Discovery of common chemical exposures across three continents using silicone wristbands. %A Holly Dixon %A Armstrong, Georgina %A Michael L Barton %A Alan J Bergmann %A Melissa Bondy %A Mary L Halbleib %A Winnifred Hamilton %A Erin N Haynes %A Julie Herbstman %A Peter D Hoffman %A Paul C Jepson %A Molly Kile %A Laurel D Kincl %A Paul J Laurienti %A Paula E North %A Paulik, L Blair %A Petrosino, Joe %A Points, Gary L %A Carolyn M Poutasse %A Diana Rohlman %A Richard P Scott %A Brian W Smith %A Lane G Tidwell %A Cheryl Walker %A Katrina M Waters %A Kim A Anderson %X

To assess differences and trends in personal chemical exposure, volunteers from 14 communities in Africa (Senegal, South Africa), North America (United States (U.S.)) and South America (Peru) wore 262 silicone wristbands. We analysed wristband extracts for 1530 unique chemicals, resulting in 400 860 chemical data points. The number of chemical detections ranged from 4 to 43 per wristband, with 191 different chemicals detected, and 1339 chemicals were not detected in any wristband. No two wristbands had identical chemical detections. We detected 13 potential endocrine disrupting chemicals in over 50% of all wristbands and found 36 chemicals in common between chemicals detected in three geographical wristband groups (Africa, North America and South America). U.S. children (less than or equal to 11 years) had the highest percentage of flame retardant detections compared with all other participants. Wristbands worn in Texas post-Hurricane Harvey had the highest mean number of chemical detections (28) compared with other study locations (10-25). Consumer product-related chemicals and phthalates were a high percentage of chemical detections across all study locations (36-53% and 18-42%, respectively). Chemical exposures varied among individuals; however, many individuals were exposed to similar chemical mixtures. Our exploratory investigation uncovered personal chemical exposure trends that can help prioritize certain mixtures and chemical classes for future studies.

%B R Soc Open Sci %V 6 %P 181836 %8 02/2019 %G eng %N 2 %R 10.1098/rsos.181836 %0 Audiovisual Material %D 2019 %T Discovery of common chemical exposures across three continents using silicone wristbands %A Holly Dixon %A Armstrong, Georgina %A Michael L Barton %A Alan J Bergmann %A Melissa Bondy %A Mary L Halbleib %A Erin N Haynes %A Julie Herbstman %A Winnifred Hamilton %A Peter D Hoffman %A Paul C Jepson %A Molly Kile %A Laurel D Kincl %A Paul J Laurienti %A Paula E North %A LB Paulik %A Petrosino, Joe %A Points, Gary L %A Carolyn M Poutasse %A Diana Rohlman %A Richard P Scott %A Brian W Smith %A Lane G Tidwell %A Cheryl Walker %A Katrina M Waters %A Kim A Anderson %B EMT Research Day, Corvallis, OR %C Corvallis, OR %8 01/2019 %G eng %0 Audiovisual Material %D 2018 %T Comparing chemical exposures across diverse communities using silicone wristbands %A Holly Dixon %A Carey E Donald %A Alan J Bergmann %A Points, Gary L %A Richard P Scott %A Brian W Smith %A Kim A Anderson %B Gordon Research Conference on Environmental Sciences: Water, Holderness, NH %C Holderness, New Hampshire %8 06/2018 %G eng %0 Audiovisual Material %D 2018 %T Comparing Chemical Exposures Across Diverse Communities Using Silicone Wristbands %A Holly Dixon %A Bergmann AJ %A Mary L Halbleib %A Erin N Haynes %A Julie Herbstman %A Peter D Hoffman %A Paul C Jepson %A Molly Kile %A Laurel D Kincl %A Paul J Laurienti %A Paula E North %A LB Paulik %A Points, Gary L %A Carolyn M Poutasse %A Diana Rohlman %A Richard P Scott %A Brian W Smith %A Lane G Tidwell %A Katrina M Waters %A Kim A Anderson %B Total Exposure Health Conference, Bethesda, MD %8 09/2018 %G eng %0 Audiovisual Material %D 2018 %T Comparing chemical exposures across diverse communities using silicone wristbands %A Holly Dixon %A Alan J Bergmann %A Mary L Halbleib %A Erin N Haynes %A Julie Herbstman %A Peter D Hoffman %A Paul C Jepson %A Molly Kile %A Laurel D Kincl %A Paul J Laurienti %A Paula E North %A LB Paulik %A Points, Gary L %A Carolyn M Poutasse %A Diana Rohlman %A Richard P Scott %A Smith BW %A Lane G Tidwell %A Katrina M Waters %A Kim A Anderson %B 3rd Tribal Environmental Health Summit, Corvallis, OR %C Corvallis, Oregon %8 06/2018 %G eng %0 Journal Article %J Anal Bioanal Chem %D 2018 %T Development of quantitative screen for 1550 chemicals with GC-MS. %A Alan J Bergmann %A Points, Gary L %A Richard P Scott %A Glenn R Wilson %A Kim A Anderson %X

With hundreds of thousands of chemicals in the environment, effective monitoring requires high-throughput analytical techniques. This paper presents a quantitative screening method for 1550 chemicals based on statistical modeling of responses with identification and integration performed using deconvolution reporting software. The method was evaluated with representative environmental samples. We tested biological extracts, low-density polyethylene, and silicone passive sampling devices spiked with known concentrations of 196 representative chemicals. A multiple linear regression (R = 0.80) was developed with molecular weight, logP, polar surface area, and fractional ion abundance to predict chemical responses within a factor of 2.5. Linearity beyond the calibration had R > 0.97 for three orders of magnitude. Median limits of quantitation were estimated to be 201 pg/μL (1.9× standard deviation). The number of detected chemicals and the accuracy of quantitation were similar for environmental samples and standard solutions. To our knowledge, this is the most precise method for the largest number of semi-volatile organic chemicals lacking authentic standards. Accessible instrumentation and software make this method cost effective in quantifying a large, customizable list of chemicals. When paired with silicone wristband passive samplers, this quantitative screen will be very useful for epidemiology where binning of concentrations is common. Graphical abstract A multiple linear regression of chemical responses measured with GC-MS allowed quantitation of 1550 chemicals in samples such as silicone wristbands.

%B Anal Bioanal Chem %V 410 %P 3101-3110 %8 2018 May %G eng %N 13 %R 10.1007/s00216-018-0997-7 %0 Generic %D 2018 %T Discovery of common chemical exposures across three continents using silicone wristbands %A Holly Dixon %A Armstrong, Georgina %A Michael L Barton %A Bergmann AJ %A Melissa Bondy %A Mary L Halbleib %A Erin N Haynes %A Julie Herbstman %A Winnifred Hamilton %A Peter D Hoffman %A Paul C Jepson %A Molly Kile %A Laurel D Kincl %A Paul J Laurienti %A Paula E North %A LB Paulik %A Petrosino, Joe %A Points, Gary L %A Carolyn M Poutasse %A Diana Rohlman %A Richard P Scott %A Brian W Smith %A Lane G Tidwell %A Cheryl Walker %A Katrina M Waters %A Kim A Anderson %B FSES External Advisory Committee Meeting, Yachats, OR %8 10/2018 %G eng %0 Generic %D 2017 %T Comparing chemical exposures across diverse communities using silicone wristbands %A Holly Dixon %A Carey E Donald %A Alan J Bergmann %A Points, Gary L %A Richard P Scott %A Brian W Smith %A Kim A Anderson %B 27th International Society of Exposure Science Annual Meeting. Research Triangle Park, North Carolina. %8 10/2017 %G eng %0 Audiovisual Material %D 2017 %T Comparing chemical exposures across diverse communities using silicone wristbands %A Holly Dixon %A Carey E Donald %A Alan J Bergmann %A Points, Gary L %A Richard P Scott %A Brian W Smith %A Kim A Anderson %B 27th International Society of Exposure Science Annual Meeting. Research Triangle Park, North Carolina %8 10/2017 %G eng %0 Journal Article %J J Expo Sci Environ Epidemiol %D 2017 %T Preparation and performance features of wristband samplers and considerations for chemical exposure assessment. %A Kim A Anderson %A Points, Gary L %A Carey E Donald %A Holly Dixon %A Richard P Scott %A Glenn R Wilson %A Lane G Tidwell %A Peter D Hoffman %A Julie Herbstman %A Steven G O'Connell %X

Wristbands are increasingly used for assessing personal chemical exposures. Unlike some exposure assessment tools, guidelines for wristbands, such as preparation, applicable chemicals, and transport and storage logistics, are lacking. We tested the wristband's capacity to capture and retain 148 chemicals including polychlorinated biphenyls (PCBs), pesticides, flame retardants, polycyclic aromatic hydrocarbons (PAHs), and volatile organic chemicals (VOCs). The chemicals span a wide range of physical-chemical properties, with log octanol-air partitioning coefficients from 2.1 to 13.7. All chemicals were quantitatively and precisely recovered from initial exposures, averaging 102% recovery with relative SD ≤21%. In simulated transport conditions at +30 °C, SVOCs were stable up to 1 month (average: 104%) and VOC levels were unchanged (average: 99%) for 7 days. During long-term storage at -20 °C up to 3 (VOCs) or 6 months (SVOCs), all chemical levels were stable from chemical degradation or diffusional losses, averaging 110%. Applying a paired wristband/active sampler study with human participants, the first estimates of wristband-air partitioning coefficients for PAHs are presented to aid in environmental air concentration estimates. Extrapolation of these stability results to other chemicals within the same physical-chemical parameters is expected to yield similar results. As we better define wristband characteristics, wristbands can be better integrated in exposure science and epidemiological studies.Journal of Exposure Science and Environmental Epidemiology advance online publication, 26 July 2017; doi:10.1038/jes.2017.9.

%B J Expo Sci Environ Epidemiol %8 2017 Jul 26 %G eng %R 10.1038/jes.2017.9 %0 Audiovisual Material %D 2015 %T Assessing Recovery, Transport, and Stability for Over 160 Compounds in Silicone Personal Passive Samplers %A Steven G O'Connell %A Points, Gary L %A Wilson, Madeline %A Kim A Anderson %B SETAC North America 36th Annual Meeting. Salt Lake City, Utah %8 11/2015 %G eng