Persistent organic pollutants carried by synthetic polymers in the ocean environment

Rios, Lorena M.; Moore, Charles J.; Jones, Patrick R.

doi:10.1016/j.marpolbul.2007.03.022

Cited by 774 publications

(400 citation statements)

References 41 publications

Supporting

Mentioning

317

Contrasting

Unclassified

Order By: Relevance

“…Early studies with PAHs spiked sediments using Arenicola marina pointed out that the solubilisation of organic chemicals is significantly increased in the presence of digestive fluids compared to seawater alone, thus increasing their bioavailability (Voparil and Mayer, 2000). (Rios et al, 2007;Karapanagioti et al, 2011). The observed behavior supports the potential of plastic micro litter in trapping and facilitating the distribution of pollutants in aquatic environments, as previously addressed by several studies aiming at calculating the partition coefficients of organic chemicals on various typologies of plastic polymers (Zarfl and Matthies, 2010;Bakir et al, 2012;Heskett et al, 2012;Mizukawa et al, 2013;Lee et al, 2014;Avio et al, 2015;Kedzierski et al, 2018).…”

Section: Discussionmentioning

confidence: 66%

Comparative Effects of Ingested PVC Micro Particles With and Without Adsorbed Benzo(a)pyrene vs. Spiked Sediments on the Cellular and Sub Cellular Processes of the Benthic Organism Hediste diversicolor

Gomiero

Strafella

Pellini³

et al. 2018

Front. Mar. Sci.

View full text Add to dashboard Cite

Plastic micro litter represents an emerging contaminant as well as a multiple stress agent in aquatic environments. Microplastics are found even in the remote areas of the world. Together with their occurrence in all environmental compartments, there is a growing concern about their potential to adsorb pollutants co-occurring in the environment. At present, little is known about this source of exposure for aquatic organisms in the benthic environment. Exposure conditions were set up to mimick the contribution of microplastics through different exposure routes. Potential biological effects resulting from these exposures were investigated in the model organism Hediste diversicolor, an annelid worm. Cellular effects including alterations of immunological responses, lysosomal compartment changes, mitochondrial activity, oxyradical production and onset of genotoxicity were assessed in coelomocytes while temporary and permanent effects of oxidative stress were also performed at tissue level. In this study polyvinylchloride (PVC) microparticles were shown to adsorb benzo(a)pyrene with a time and dose-dependent relationship. The elevated bioavailability of the model pollutant after ingestion induced a clear pattern of biological responses. Toxicity mainly targeted impairment of cellular functioning and genotoxicity in H. diversicolor coelomocytes, while permanent effects of oxidative stress were observed at tissue level. Coelomocytes responded fast and with a higher degree of sensitivity to the adverse stimuli. The results showed that microplastic particles in sediments may play a significant role as vectors for organic pollutants. The highest adverse responses were observed in those H. diversicolor exposed to sediments spiked with PVC particles pre-incubated with B[a]P when compared against sediments spiked with B[a]P and plastic microparticles separately.

show abstract

Section: Discussionmentioning

confidence: 66%

Comparative Effects of Ingested PVC Micro Particles With and Without Adsorbed Benzo(a)pyrene vs. Spiked Sediments on the Cellular and Sub Cellular Processes of the Benthic Organism Hediste diversicolor

Gomiero

Strafella

Pellini³

et al. 2018

Front. Mar. Sci.

View full text Add to dashboard Cite

show abstract

“…Until now, only a limited number of global surveys have been conducted on the quantity and distribution of microplastics in the oceans (Lusher 2015). Most surveys focused on specific oceanic regions and habitats, such as coastal areas, regional seas, gyres or the poles (Thompson et al 2004, Collignon et al 2012Rios and Moore 2007). Concentrations of microplastics at sea vary from thousands to hundreds of thousands of particles km −2 and latest reports suggest that microplastic pollution has spread throughout the world's oceans from the water column (Lattin et al 2010;Cole et al 2011) to sediments even of the deep sea (Moore et al 2001b;Law et al 2010;Claessens et al 2011;Cole et al 2011;Collignon et al 2012;Erikssen et al 2014;Reisser et al 2013;van Cauwenberghe et al 2013;Fischer et al 2015).…”

Section: Microplasticsmentioning

confidence: 99%

Global Distribution, Composition and Abundance of Marine Litter

Galgani

Hanke

Maes

2015

Marine Anthropogenic Litter

433

338

View full text Add to dashboard Cite

Marine debris is commonly observed everywhere in the oceans. Litter enters the seas from both land-based sources, from ships and other installations at sea, from point and diffuse sources, and can travel long distances before being stranded. Plastics typically constitute the most important part of marine litter sometimes accounting for up to 100 % of floating litter. On beaches, most studies have demonstrated densities in the 1 item m −2 range except for very high concentrations because of local conditions, after typhoons or flooding events. Floating marine debris ranges from 0 to beyond 600 items km −2 . On the sea bed, the abundance of plastic debris is very dependent on location, with densities ranging from 0 to >7700 items km −2 , mainly in coastal areas. Recent studies have demonstrated that pollution of microplastics, particles <5 mm, has spread at the surface of oceans, in the water column and in sediments, even in the deep sea. Concentrations at the water surface ranged from thousands to hundred thousands of particles km −2 . Fluxes vary widely with factors such as proximity of urban activities, shore and coastal uses, wind and ocean currents. These enable the presence of accumulation areas in oceanic convergence zones and on the seafloor, notably in coastal canyons. Temporal trends are not clear with evidences for increases, decreases or without changes, depending on locations and environmental conditions. In terms of distribution and quantities, proper global estimations based on standardized approaches are still needed before considering efficient management and reduction measures.

show abstract

“…Another more alarming aspect is that microplastics can release toxic additives and they are known to accumulate persistent organic pollutants (POPs). [32][33][34][35][36] Hence, when microplastics, because of their minuteness, enter marine food webs at low trophic levels they simultaneously harbour the risk of potentially propagating these toxic substances up the food chain. [37,38] This issue is discussed controversially in recent research and although several studies suggest it being of minor importance from a risk assessment perspective [39,40] microplastics have the potential to transport POPs to human food.…”

Section: Introductionmentioning

confidence: 99%

Focal plane array detector-based micro-Fourier-transform infrared imaging for the analysis of microplastics in environmental samples

et al. 2015

View full text Add to dashboard Cite

Environmental context. Microplastics are of increasing environmental concern following reports that they occur worldwide from the arctic to the deep sea. However, a reliable methodology that facilitates an automated measurement of abundance and identity of microplastics is still lacking. We present an analytical protocol that applies focal plane array detector-based infrared imaging of microplastics enriched on membrane filters applicable to investigations of microplastic pollution of the environment.Abstract. The pollution of the environment with microplastics (plastic pieces ,5 mm) is a problem of increasing concern. However, although this has been generally recognised by scientists and authorities, the analysis of microplastics is often done by visual inspection alone with potentially high error rates, especially for smaller particles. Methods that allow for a fast and reliable analysis of microplastics enriched on filters are lacking. Our study is the first to fill this gap by using focal plane array detector-based micro-Fourier-transform infrared imaging for analysis of microplastics from environmental samples. As a result of our iteratively optimised analytical approach (concerning filter material, measuring mode, measurement parameters and identification protocol), we were able to successfully measure the whole surface (>10-mm diameter) of filters with microplastics from marine plankton and sediment samples. The measurement with a high lateral resolution allowed for the detection of particles down to a size of 20 mm in only a fractional part of time needed for chemical mapping. The integration of three band regions facilitated the pre-selection of potential microplastics of the ten most important polymers. Subsequent to the imaging the review of the infrared spectra of the pre-selected potential microplastics was necessary for a verification of plastic polymer origin. The approach we present here is highly suitable to be implemented as a standard procedure for the analysis of small microplastics from environmental samples. However, a further automatisation with respect to measurement and subsequent particle identification would facilitate the even faster and fully automated analysis of microplastic samples.

show abstract

Persistent organic pollutants carried by synthetic polymers in the ocean environment

Cited by 774 publications

References 41 publications

Comparative Effects of Ingested PVC Micro Particles With and Without Adsorbed Benzo(a)pyrene vs. Spiked Sediments on the Cellular and Sub Cellular Processes of the Benthic Organism Hediste diversicolor

Comparative Effects of Ingested PVC Micro Particles With and Without Adsorbed Benzo(a)pyrene vs. Spiked Sediments on the Cellular and Sub Cellular Processes of the Benthic Organism Hediste diversicolor

Global Distribution, Composition and Abundance of Marine Litter

Focal plane array detector-based micro-Fourier-transform infrared imaging for the analysis of microplastics in environmental samples

Contact Info

Product

Resources

About