%0 Journal Article %J Chemosphere %D 2010 %T Exploiting lipid-free tubing passive samplers and embryonic zebrafish to link site specific contaminant mixtures to biological responses. %A Hillwalker, Wendy E %A Sarah E Allan %A Robyn L Tanguay %A Kim A Anderson %K Animals %K Embryo, Nonmammalian %K Embryonic Development %K Environmental Monitoring %K Lipids %K Rivers %K Water Pollutants, Chemical %K Zebrafish %X

The Biological Response Indicator Devices Gauging Environmental Stressors (BRIDGES) bio-analytical tool was developed in response to the need for a quantitative technology for assessing the toxicity of environmentally relevant contaminant mixtures. This tool combines passive samplers with the embryonic zebrafish model. When applied in an urban river it effectively linked site specific, bioavailable contaminant mixtures to multiple biological responses. Embryonic zebrafish exposed to extracts from lipid-free passive samplers that were deployed at five locations, within and outside of the Portland Harbor Superfund Megasite, displayed different responses. Six of the eighteen biological responses observed in 941 exposed zebrafish were significantly different between sites. This demonstrates the sensitivity of the bio-analytical tool for detecting spatially distinct toxicity in aquatic systems; bridging environmental exposure to biological response.

%B Chemosphere %V 79 %P 1-7 %8 03/2010 %G eng %N 1 %1 http://www.ncbi.nlm.nih.gov/pubmed/20172587?dopt=Abstract %R 10.1016/j.chemosphere.2010.02.001 %0 Journal Article %J Environ Sci Technol %D 2008 %T Field trial and modeling of uptake rates of in situ lipid-free polyethylene membrane passive sampler. %A Kim A Anderson %A D Sethajintanin %A Gregory J Sower %A Quarles, L %K Lipids %K Membranes, Artificial %K Models, Molecular %K Models, Theoretical %K Polyethylene %K Quality Control %X

Lipid-free polyethylene membrane tubing (LFT) has been further developed in response to a growing need for an inexpensive and simple time-integrative sampling device for dissolved hydrophobic contaminants in water. The LFT sampler is based on the diffusion of dissolved hydrophobic target compounds through the aqueous boundary layer and into the polyethylene membrane, mimicking uptake by organisms. We demonstrate through laboratory and field validation studies that LFT provided the same benefits as many other passive sampling devices, withoutthe potential of analytical interference from lipid impurities. A total of 370 LFTs and semipermeable membrane devices were deployed for 21 days in paired studies at highly urbanized, undeveloped, and two Superfund sites, representing several river conditions. A simple internal surrogate spiking method served as an in situ calibration indicator of the effects of environmental conditions on the uptake rates. A modified extraction method for the LFT increased recoveries while decreasing solvent use and labor compared to other organic extraction procedures. LFT sampling rates were estimated using ratios, in situ calibration and modeling for over 45 target analytes, including PAHs, PCBs, and pesticides.

%B Environ Sci Technol %V 42 %P 4486-93 %8 06/2008 %G eng %N 12 %1 http://www.ncbi.nlm.nih.gov/pubmed/18605575?dopt=Abstract