Silicone Wristband Passive Samplers Yield Highly Individualized Pesticide Residue Exposure Profiles

Aerts, Raf; Joly, Laure; Szternfeld, Philippe; Tsilikas, Khariklia; Cremer, Koen De; Castelain, Philippe; Aerts, Jean‐Marie; Orshoven, Jos Van; Somers, Ben; Hendrickx, Marijke; Andjelković, Mirjana; Nieuwenhuyse, An Van

doi:10.1021/acs.est.7b05039

Cited by 56 publications

(47 citation statements)

References 86 publications

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“…We used data from these wristbands to learn about chemical exposures in this population, including common chemical exposures, relations between chemical exposures, predictors of chemical exposures, and common chemical exposure profiles. Our findings suggest that these silicone wristbands can be successfully deployed within sensitive populations to assess multipollutant exposures, extending the potential uses of this technology beyond previously successful investigations ( 15 , 16 , 18 , 21 – 23 ).…”

Section: Discussionmentioning

confidence: 67%

“…This emerging technology has been applied in several settings (15), including the assessment of exposures to flame retardants among maternal-child pairs (21) and school children (18) and the assessment of exposures to pesticides among agricultural workers (22) and non-occupationally exposed persons (23). However, there is limited evidence characterizing their use among pregnant populations; to date, a single study has used the wristbands to assess exposures to PAHs among pregnant women (16) and no studies have reported on their use to assess multipollutant exposures of many chemical classes.…”

Section: Introductionmentioning

confidence: 99%

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Assessment of Multipollutant Exposures During Pregnancy Using Silicone Wristbands

Doherty

Pearce

Anderson

et al. 2020

Front. Public Health

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Section: Discussionmentioning

confidence: 67%

Section: Introductionmentioning

confidence: 99%

Assessment of Multipollutant Exposures During Pregnancy Using Silicone Wristbands

Doherty

Pearce

Anderson

et al. 2020

Front. Public Health

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“…Chromatographic cleanup procedures previously used for analysis of organic pollutants in wristbands include Florisil [12], C 18 solid phase extraction cartridges [4], and 5% acid silica columns [13]. Some other methods (mostly focusing on the screening of analytes) did not include any cleanup or fractionation [5,7,14]. In the initial trials, we found several interferences in the extracts that were limiting the analysis of some target analytes: one was siloxane, which was released from the wristbands during extraction; the other were lipids, which were transferred from the skin to the wristbands during deployment due to the direct skin-wristband contact.…”

Section: Chromatographic Cleanupmentioning

confidence: 99%

Analysis of brominated and chlorinated flame retardants, organophosphate esters, and polycyclic aromatic hydrocarbons in silicone wristbands used as personal passive samplers

Romanak

Wang

Stubbings

et al. 2019

Journal of Chromatography A

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For the first time, we present an analytical method to simultaneously extract, fractionate, and quantify four groups of semi-volatile organic compounds (SVOCs) in silicone wristbands, including 35 polybrominated diphenyl ethers (PBDEs), 10 novel flame retardants (NFRs), 19 organophosphate esters (OPEs), and 13 polycyclic aromatic hydrocarbons (PAHs). Wristbands were extracted using ultrasonication, and cleaned and fractionated on two multi-layer columns: one consisting of neutral alumina, neutral silica and Florisil, and the other consisting of neutral alumina, neutral silica, and acidic silica. Method accuracy and precision were validated using spiked wristband samples (n = 8) and procedural blanks (n = 7). Average matrix spike percent recoveries for all target analytes were within 57 -107% with relative standard errors < 20%, with a few exceptions. This method was applied to analyze thirteen wristbands worn by ten participants for seven days; three participants wore two wristbands to evaluate duplicate samples. Percent recoveries of surrogate standards for all four groups of analytes in these wristbands were all within the 80 -120% range with a few exceptions: recoveries for 13 C 12 BDE-209 and for 13 C 12 -triphenyl phosphate ranged from 35 -62% and 69 -176%, respectively. The majority of target analytes were detected in at least half of worn wristbands. The levels of total PBDEs, NFRs, OPEs and PAHs in deployed wristbands ranged from 28.4 to 412 ng, 40.7 to 625 ng, 2,440 to 9,580 ng, and 76.2 to 1,240 ng, respectively.We developed an efficient method for the determination of a total of 77 analytes, including 35 PBDEs, 10 NFRs, 19 OPEs, and 13 PAHs, in silicone wristbands. This method offers a solution to chromatographic interferences associated with siloxanes from the wristband Romanak et al. Highlights •Silicone wristbands are a novel tool for assessing personal exposures • This is the first method for simultaneous quantitative analysis of 77 SVOCs 35 PBDEs, 9 NFRs, 19 OPEs, and 13 PAHs were simultaneously extracted and analyzed Romanak et al. •

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“…This study also provides a method that allows researchers to quantitatively compare hive chemical profiles without needing to determine compound concentrations in the air of each hive. Previous studies have shown that the consistent adsorption of silicone bands allow samples to be compared without the need for further calculations, provided the dimensions of the silicone sampler and deployment length are the same [ 25 , 48 ]. Silicone bands are more consistent in their compound adsorption ratios than several other passive samplers such as polyurethane foam, urine sampling, and hand wipes [ 25 , 26 ], potentially because the silicone matrix stabilizes compounds until extraction [ 24 ].…”

Section: Discussionmentioning

confidence: 99%

Silicone Wristbands as Passive Samplers in Honey Bee Hives

Bullock

Schafsnitz

Wang

et al. 2020

Veterinary Sciences

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The recent decline of European honey bees (Apis mellifera) has prompted a surge in research into their chemical environment, including chemicals produced by bees, as well as chemicals produced by plants and derived from human activity that bees also interact with. This study sought to develop a novel approach to passively sampling honey bee hives using silicone wristbands. Wristbands placed in hives for 24 h captured various compounds, including long-chain hydrocarbons, fatty acids, fatty alcohols, sugars, and sterols with wide ranging octanol–water partition coefficients (Kow) that varied by up to 19 orders of magnitude. Most of the compounds identified from the wristbands are known to be produced by bees or plants. This study indicates that silicone wristbands provide a simple, affordable, and passive method for sampling the chemical environment of honey bees.

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Silicone Wristband Passive Samplers Yield Highly Individualized Pesticide Residue Exposure Profiles

Cited by 56 publications

References 86 publications

Assessment of Multipollutant Exposures During Pregnancy Using Silicone Wristbands

Assessment of Multipollutant Exposures During Pregnancy Using Silicone Wristbands

Analysis of brominated and chlorinated flame retardants, organophosphate esters, and polycyclic aromatic hydrocarbons in silicone wristbands used as personal passive samplers

Silicone Wristbands as Passive Samplers in Honey Bee Hives

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