Passive sampling: Difference between revisions

'''Passive sampling''' is an [[environmental monitoring]] technique involving the use of a collecting medium, such as a man-made device or biological [[organism]], to accumulate chemical [[pollutant]]s in the environment over time. This is in contrast to [[Environmental monitoring#Grab samples|grab sampling]], which involves taking a sample directly from the media of interest at one point in time. In passive sampling, average chemical concentrations are calculated over a device's deployment time, which avoids the need to visit a sampling site multiple times to collect multiple representative samples.<ref name = Main>{{cite journal |last1=Górecki |first1=Tadeusz |last2=Namieśnik |first2=Jacek |title=Passive sampling |journal=Trends in Analytical Chemistry |date=2002 |volume=21 |issue=4 |pages=276–291 |doi=10.1016/S0165-9936(02)00407-7 }}</ref> Currently, passive samplers have been developed and deployed to detect toxic metals, [[pesticide]]s, [[Drug|pharmaceuticals]], [[radionuclide]]s, [[polycyclic aromatic hydrocarbon]]s (PAHs), [[polychlorinated biphenyl]]s (PCBs), and other organic compounds in water,<ref name = Chem1>{{cite journal |last1=Charriau |first1=Adeline |last2=Lissalde |first2=Sophie |last3=Poulier |first3=Gaëlle |last4=Mazzella |first4=Nicolas |last5=Buzier |first5=Rémy |last6=Guibaud |first6=Gilles |title=Overview of the Chemcatcher® for the passive sampling of various pollutants in aquatic environments Part A: Principles, calibration, preparation and analysis of the sampler |journal=Talanta |date=2016 |volume=148 |doi=10.1016/j.talanta.2015.06.064 |pages=556–571|pmid=26653485 }}</ref><ref name = Chem2>{{cite journal |last1=Lissalde |first1=Sophie |last2=Charriau |first2=Adeline |last3=Poulier |first3=Gaëlle |last4=Mazzella |first4=Nicolas |last5=Buzier |first5=Rémy |last6=Giubaud |first6=Giles |title=Overview of the Chemcatcher® for the passive sampling of various pollutants in aquatic environments Part B: Field handling and environmental applications for the monitoring of pollutants and their biological effects |journal=Talanta |date=2016 |volume=148 |doi=10.1016/j.talanta.2015.06.076 |pages=572–582|pmid=26653486 }}</ref><ref name = Brumbaugh>{{cite journal |last1=Brumbaugh |first1=WG |last2=Petty |first2=JD |last3=Huckins |first3=JN |last4=Manahan |first4=SE |title=Stabilized Liquid Membrane Device (SLMD) for the Passive, Integrative Sampling of Labile Metals in Water |journal=Water, Air, and Soil Pollution |date=2002 |volume=133 |pages=109–119 |doi=10.1023/A:1012923529742 |bibcode=2002WASP..133..109B |s2cid=93497819 }}</ref><ref name = POCISSPMD>{{cite web |title=Guidelines for the Use of the Semipermeable Membrane Device (SPMD) and the Polar Organic Chemical Integrative Sampler (POCIS) in Environmental Monitoring Studies |url=https://pubs.usgs.gov/tm/tm1d4/ |publisher=United States Geological Survey |access-date=30 May 2018}}</ref> while some passive samplers can detect hazardous substances in the air.<ref name = Sigma>{{cite web |title=Passive (Diffusive) Sampling Overview |url=https://www.sigmaaldrich.com/analytical-chromatography/air-monitoring/passive-sampling.html |website=Sigma-Aldrich |access-date=31 May 2018}}</ref><ref name = LichData>{{cite web |title=Lichen Monitoring in US National Forests and Parks Reports, Publications and Other Resources |url=http://gis.nacse.org/lichenair/?page=reports |website=National Lichens & Air Quality Database and Clearinghouse |publisher=United States Forest Service |access-date=31 May 2018}}</ref><ref name = Tubes />

*[[DioxinDioxins and dioxin-like compounds|Dioxins]]s<ref name = POCISSPMD />

Several kinds of passive sampling devices exist for monitoring pollutants present in water. In addition to these devices, organisms, such as [[mussel]]s, living in the environment also "passively sample" contaminants ([[bioaccumulation]]) and can be used to monitor water pollution ([[Aquatic biomonitoring|biomonitoring]]).<ref name="Mussel">{{cite journal |last1=Sericano |first1=JL |last2=Wade |first2=TL |last3=Jackson |first3=TJ |last4=Brooks |first4=JM |last5=Tripp |first5=BW |last6=Farrington |first6=JW |last7=Mee |first7=LD |last8=Readmann |first8=JW |last9=Villeneuve |first9=JP |last10=Goldberg |first10=ED |title=Trace Organic Contamination in the Americas: An Overview of the US National Status & Trends and the International 'Mussel Watch' Programmes |journal=Marine Pollution Bulletin |date=1995 |volume=31 |issue=4–12|pages=214–225 |doi=10.1016/0025-326X(95)00197-U |bibcode=1995MarPB..31..214S }}</ref>

Diffusive gradients in thin films (DGT) samplers passively sample [[ion]]ic trace metals, as well as [[antibiotic]]s, [[oxyanion]]s, [[bisphenol]]s, and [[nanoparticle]]s in different configurations. They are composed of plastic pistons and caps, with a window that exposes a binding gel, diffusive gel, and filter membrane to the sampling water. They can be used in both freshwater and marine environments, as well as in the water located between freshwater and marine [[sediment]] particles, called ''pore water'' or ''interstitial water''. Once the mass of accumulated contaminants on the DGT sampler is known, the DGT equation (based on [[Fick's law]]) can be used to calculate the time averaged water concentration of contaminants.<ref name="DGT">{{cite journal |last1=Zhang |first1=Chaosheng |last2=Ding |first2=Shiming |last3=Xu |first3=Di |last4=Tang |first4=Ya |last5=Wong |first5=Ming H |title=Bioavailability assessment of phosphorus and metals in soils and sediments: a review of diffusive gradients in thin films (DGT) |journal=Environmental Monitoring and Assessment |date=2014 |volume=186 |issue=11|pages=7367–7378 |doi=10.1007/s10661-014-3933-0 |pmid=25015347 |bibcode=2014EMnAs.186.7367Z |s2cid=25854461 }}</ref>

Microporous polyethylene tubes (MPT) attempt to mitigate the flow-dependency of other kinetic passive samplers such as Chemcatcher and POCIS by introducing a thicker membrane .<ref>{{Cite journal|lastlast1=Fauvelle|firstfirst1=Vincent|last2=Kaserzon|first2=Sarit L.|last3=Montero|first3=Natalia|last4=Lissalde|first4=Sophie|last5=Allan|first5=Ian J.|last6=Mills|first6=Graham|last7=Mazzella|first7=Nicolas|last8=Mueller|first8=Jochen F.|last9=Booij|first9=Kees|date=2017-03-07|title=Dealing with Flow Effects on the Uptake of Polar Compounds by Passive Samplers|url=https://doi.org/10.1021/acs.est.7b00558|journal=Environmental Science & Technology|volume=51|issue=5|pages=2536–2537|doi=10.1021/acs.est.7b00558|pmid=28225255|bibcode=2017EnST...51.2536F|s2cid=206567423 |issn=0013-936X|doi-access=free}}</ref>. The diffusive polyethylene layer prevents the thickness of the water-boundary layer (which is affected by flow) from dominating diffusion.<ref name=":0">{{Cite journal|lastlast1=Fauvelle|firstfirst1=Vincent|last2=Montero|first2=Natalia|last3=Mueller|first3=Jochen F.|last4=Banks|first4=Andrew|last5=Mazzella|first5=Nicolas|last6=Kaserzon|first6=Sarit L.|date=2017|title=Glyphosate and AMPA passive sampling in freshwater using a microporous polyethylene diffusion sampler|url=https://pubmed.ncbi.nlm.nih.gov/28886558/|journal=Chemosphere|volume=188|pages=241–248|doi=10.1016/j.chemosphere.2017.08.013|issn=1879-1298|pmid=28886558|bibcode=2017Chmsp.188..241F}}</ref>. The tube is filled with sorbents depending on the chemicals or chemical groups being sampled and has been successfully used to sample glyphosate, AMPA<ref name=":0" />, illicit drugs and pharmaceuticals and personal care products.<ref name=":0" /><ref>{{Cite journal|date=2020-02-20|title=Calibration and validation of a microporous polyethylene passive sampler for quantitative estimation of illicit drug and pharmaceutical and personal care product (PPCP) concentrations in wastewater influent|url=https://www.sciencedirect.com/science/article/abs/pii/S0048969719358863|journal=Science of Thethe Total Environment|language=en|volume=704|pagesarticle-number=135891|doi=10.1016/j.scitotenv.2019.135891|issn=0048-9697|last1=McKay|first1=Sarah|last2=Tscharke|first2=Ben|last3=Hawker|first3=Darryl|last4=Thompson|first4=Kristie|last5=O'Brien|first5=Jake|last6=Mueller|first6=Jochen F.|last7=Kaserzon|first7=Sarit|pmid=31838300|bibcode=2020ScTEn.70435891M|s2cid=209386153 |url-access=subscription|hdl=10072/396186|hdl-access=free}}</ref>.

Peepers are passive [[diffusion]] samplers used for metals in freshwater and marine [[sediment]] pore water, so they can be used to find areas that may have metal-contaminated sediments. Peepers are plastic vessels filled with clean water and covered in a [[Dialysis (biochemistry)|dialysis membrane]], which allows metals in sediment pore water to enter the water inside the peeper.<ref name="Peeper1">{{cite journal |last1=Serbst |first1=JR |last2=Burgess |first2=RM |last3=Kuhn |first3=A |last4=Edwards |first4=PA |last5=Cantwell |first5=MG |title=Precision of Dialysis (Peeper) Sampling of Cadmium in Marine Sediment Interstitial Water |journal=Archives of Environmental Contamination and Toxicology |date=2003 |volume=45 |issue=3 |pages=297–305 |pmid=14674581 |doi=10.1007/s00244-003-0114-5|bibcode=2003ArECT..45..297S |s2cid=23462490 }}</ref> They are usually placed deep enough into sediment to be in an [[Anoxic waters|anoxic]] environment, in which metals will be soluble enough to sample.<ref name = Missouri /> If the peepers are deployed long enough so the sediment pore water and contained peeper water reach equilibrium, they can accurately provide metal concentrations in sampled sediment pore water.<ref name = Peeper1 />

Semipermeable membrane devices (SPMDs) passively sample [[Chemical polarity|nonpolar]] organic contaminants with a log octanol-water partition coefficient (K_ow) value greater than 3. Examples of these types of chemicals include [[polycyclic aromatic hydrocarbons]] (PAHs), [[polychlorinated biphenyls]] (PCBs), [[polybrominated diphenyl ethers]] (PBDEs), chlorinated pesticides, [[dioxinPolychlorinated dibenzodioxins|dioxins]]s, and [[furanPolychlorinated dibenzofurans|furans]]s. SPMDs are composed of sealed plastic tubing filled with [[triolein]], in which nonpolar organics are very soluble and which serves as a representation of the fatty tissues of aquatic organisms. The tubing is then weaved between metal rods and enclosed in a metal cage. The sampler can be made in varying lengths of tubing for different applications, since sampling rate depends on the surface area of tubing exposed to the water. As long as the amount of water passing over the sampler is known, nonpolar organic contaminant water concentrations can be calculated after extracting contaminants from a SPMD.<ref name = POCISSPMD />

Stabilized liquid membrane devices (SLMDs) passively sample [[ion]]ic metals in freshwater. They are made of [[low-density polyethylene]] plastic tubing sections that are sealed on both ends and filled with an equal mixture of [[oleic acid]] and metal [[Chelation|chelating agent]]. They work by interacting with calcium and magnesium ions in freshwater, which forms a hydrophobic film on the outside the SLMD plastic membrane in which the chelating agent can bind to metals in the sampling water.<ref name = Brumbaugh /> They have been deployed for up to month-long periods in the field, alone or covered by a plastic tube housing to mediate water flow.<ref name="Missouri">{{cite journal |last1=Brumbaugh |first1=William G |last2=May |first2=Thomas W |last3=Besser |first3=John M |last4=Allert |first4=Ann L |last5=Schmitt |first5=Christopher J |title=Assessment of Elemental Concentrations in Streams of the New Lead Belt in Southeastern Missouri, 2002–05 |journal=USGS Report |series=Scientific Investigations Report |date=2007 |page=78 |publisher=United States Geological Survey|doi=10.3133/sir20075057 |bibcode=2007usgs.rept...78B }}</ref> Metal weight accumulated by a SLMD over its deployment period can be calculated and divided by the SLMD deployment time to get an average metal weight accumulated per time unit, but currently, no method has been developed to convert this to an average metal concentration. In addition, SLMD sampling rates greatly vary with water flow rate, which plastic housings can be used to control.<ref name = Brumbaugh /><ref name = Missouri />

Passive sampling can also be accomplished for contaminants in the air, including airborne particles and hazardous vapors and gases. This can be done with man-made devices or with biomonitoring organisms, such as [[Lichen#Effects of air pollution|lichens]].<ref name = LichData /><ref name="Lichen">{{cite journal |last1=Garty |first1=J |title=Biomonitoring Atmospheric Heavy Metals with Lichens: Theory and Application |journal=Critical Reviews in Plant Sciences |date=2001 |volume=20 |issue=4 |pages=309–371 |doi=10.1080/20013591099254 |bibcode=2001CRvPS..20..309G |s2cid=59062166 }}</ref>

Contaminant concentrations from passive sampling reflect average contamination throughout the sampler deployment time, meaning the sample will capture contaminant concentration fluctuations over the whole deployment period. Traditional grab sampling does not do this, since collected samples only represent a single moment in time and multiple grab samples must be taken to observe variation in contaminant concentrations over time.<ref name = Main /> This integrative sampling method can also can result in the detection of chemicals present at such low concentrations that they would be undetected in a grab sample, due to concentration of the chemicals on the sampler over time. As a result, passive sampling has the potential to be a less time-intensive, less expensive and more accurate sampling method than grab sampling.