Occurrence and Characteristics of Microplastic Pollution in Xiangxi Bay of Three Gorges Reservoir, China

Zhang, Kai; Xiong, Xiong; Hu, Hongjuan; Wu, Chenxi; Bi, Yonghong; Wu, Yonghong; Zhou, Bingsheng; Lam, Paul K.S.; Liu, Jiantong

doi:10.1021/acs.est.7b00369

Cited by 413 publications

(118 citation statements)

References 53 publications

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“…The lowest counts were collected at nonurban coastal stations and offshore basin stations, with the exception of the deepest point of the Eastern Basin of Lake Erie (Figures 3, 4B). These findings support previous reports of a correlation between plastic concentrations and proximity to urban centers in the Great Lakes (Baldwin et al, 2016), as well as other enclosed and semi-enclosed aquatic environments across the world, such as, tributaries to the Chesapeake Bay, USA (Yonkos et al, 2014), the Bay of Brest in France (Frère et al, 2017), the Xiangzi Bay upstream of the three Gorges Dam (Zhang et al, 2017), inland lakes around Wuhan, China (Wang et al, 2017), and estuaries in and around Durban, South Africa (Naidoo et al, 2015). Attributes that are likely to contribute to elevated plastic concentrations in urban vs. nonurban locales include higher population densities (Jambeck et al, 2015), increased particulate aeolian inputs (including plastic; Dris et al, 2015), and increased areas of impervious substrate.…”

Section: Plastic Concentrations Were Highest At Urban Centerssupporting

confidence: 91%

“…These findings are consistent with surveys of other lakes, such as, lakes near Wuhan, China where more than 80% of the plastics found were 2 mm and smaller (Wang et al, 2017). However, plastics 1-5 mm in size were most abundant in sections of the Xiangxi River, perhaps due to a shorter residence time and less weathering while in the river (Zhang et al, 2017). Previous surveys of Great Lakes plastic have found a 40-and 6-fold difference between the smallest and largest size classes (Eriksen et al, 2013;Mason et al, 2016).…”

Section: Plastic Less Than 1 MM Dominated the Datasetsupporting

confidence: 89%

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Distribution and Modeled Transport of Plastic Pollution in the Great Lakes, the World's Largest Freshwater Resource

Cable

Beletsky

et al. 2017

Front. Environ. Sci.

112

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Most plastic pollution originates on land. As such, freshwater bodies serve as conduits for the transport of plastic litter to the ocean. Understanding the concentrations and fluxes of plastic litter in freshwater ecosystems is critical to our understanding of the global plastic litter budget and underpins the success of future management strategies. We conducted a replicated field survey of surface plastic concentrations in four lakes in the North American Great Lakes system, the largest contiguous freshwater system on the planet. We then modeled plastic transport to resolve spatial and temporal variability of plastic distribution in one of the Great Lakes, Lake Erie. Triplicate surface samples were collected at 38 stations in mid-summer of 2014. Plastic particles >106 µm in size were quantified. Concentrations were highest near populated urban areas and their water infrastructure. In the highest concentration trawl, nearly 2 million fragments km −2 were found in the Detroit River-dwarfing previous reports of Great Lakes plastic abundances by over 4-fold. Yet, the accuracy of single trawl counts was challenged: within-station plastic abundances varied 0-to 3-fold between replicate trawls. In the smallest size class (106-1,000 µm), false positive rates of 12-24% were determined analytically for plastic vs. non-plastic, while false negative rates averaged ∼18%. Though predicted to form in summer by the existing Lake Erie circulation model, our transport model did not predict a permanent surface "Lake Erie Garbage Patch" in its central basin-a trend supported by field survey data. Rather, general eastward transport with recirculation in the major basins was predicted. Further, modeled plastic residence times were drastically influenced by plastic buoyancy. Neutrally buoyant plastics-those with the same density as the ambient water-were flushed several times slower than plastics floating at the water's surface and exceeded the hydraulic residence time of the lake. It is likely that the ecosystem impacts of plastic litter persist in the Great Lakes longer than assumed based on lake flushing rates. This study furthers our understanding of plastic pollution in the Great Lakes, a model freshwater system to study the movement of plastic from anthropogenic sources to environmental sinks.

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Section: Plastic Concentrations Were Highest At Urban Centerssupporting

confidence: 91%

Section: Plastic Less Than 1 MM Dominated the Datasetsupporting

confidence: 89%

Distribution and Modeled Transport of Plastic Pollution in the Great Lakes, the World's Largest Freshwater Resource

Cable

Beletsky

et al. 2017

Front. Environ. Sci.

112

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“…Plastic debris was observed in 141 gastrointestinal tracts of fish samples (n = 279) covering all 9 fish species with a detection frequency of 15.8 to 75.0%, and a total of 1945 particles were extracted with a mean abundance of 7.0 ± 23.8 (±SD) items per individual (range not detected-247 items/individual; Table 1), indicating that plastic ingestion was omnipresent in wild freshwater fish in the Pearl River catchment. The detection frequencies observed in the present study were higher than those of fish from French rivers (12%; Sanchez et al 2014); comparable to those of fish from the Three Gorges Reservoir of China (25.7%; Zhang et al 2017), the English Channel (36.5%; Lusher et al 2013), and the River Thames (∼76%; McGoran et al 2017); and lower than those of fish from Taihu Lake, the Yangtze River estuary, and the South China Sea (95.7-100%; Jabeen et al 2017). However, the detected abundance of plastic debris in the wild freshwater fish from the Pearl River catchment was higher than that in coastal and freshwater fish from southeast China (Jabeen et al 2017); freshwater fish from the Three Gorges Reservoir (Zhang et al 2017); marine mussels from Avery Point, Connecticut, USA (Zhao et al 2018); and tadpoles from small water bodies of the Yangtze River delta, © 2019 SETAC wileyonlinelibrary.com/ETC China (Hu et al 2018), suggesting more serious plastic pollution in the Pearl River catchment.…”

Section: Occurrence Of Plastic Debris In Freshwater Fishsupporting

confidence: 67%

Occurrence and Species‐Specific Distribution of Plastic Debris in Wild Freshwater Fish from the Pearl River Catchment, China

Zheng

Fan

Zhu

et al. 2019

Enviro Toxic and Chemistry

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Freshwater systems are an important source and vector of plastic debris found in oceans. However, plastic debris in freshwater organisms has not been well studied. The occurrence, characterization, polymer composition, and seasonal and spatial distribution of plastic debris were investigated in 9 species of wild freshwater fish from the Pearl River catchment, south China. Approximately 50% of the total fish (n = 279) belonging to 9 species were found to ingest plastic debris with an average abundance of 7.0 ± 23.8 items/individual, indicating wide plastic contamination in the Pearl River catchment. Plastic debris were predominantly transparent or white in color, fibers or fragments in shape, and polyethylene, polypropylene, ethylene–propylene copolymer (PE‐PP), and polyethylene terephthalate (PET) in polymer composition. A species‐specific distribution of the plastic debris was observed in terms of abundance, shape, and polymer composition. Redbelly tilapia had the highest (27.4 ± 54.0 items/individual), whereas common carp had the lowest (0.2 ± 0.4 items/individual) abundance of the plastic debris in their gastrointestinal tracts. Fibers of PET were predominant in the freshwater species except in barbel chubs, which had mostly PE‐PP fragments. Omnivores and bottom‐dwellers were more likely to ingest plastic debris. Seasonal variation was observed, with generally higher abundance of plastic debris in fish collected in the dry season than in the wet season. Environ Toxicol Chem 2019;38:1504–1513. © 2019 SETAC

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“…Microplastic concentrations were negatively correlated with water velocity. The authors hypothesized that dams might contribute to accumulations of less dense microplastics, as did K. Zhang et al () investigating distributions of microplastics in the Yangtze River near the Three Gorges Dam in China. McCormick et al () observed microplastic concentrations increased from upstream (1.94 ± 0.81 particles m −3 ) to downstream (18 ± 11 particles/m 3 ) sites in the Illinois River, a tributary of the Mississippi.…”

Section: Microplastics In Freshwatersmentioning

confidence: 95%

A Global Perspective on Microplastics

Hale¹,

Seeley²,

Guardia³

et al. 2020

JGR Oceans

550

228

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Society has become increasingly reliant on plastics since commercial production began in about 1950. Their versatility, stability, light weight, and low production costs have fueled global demand. Most plastics are initially used and discarded on land. Nonetheless, the amount of microplastics in some oceanic compartments is predicted to double by 2030. To solve this global problem, we must understand plastic composition, physical forms, uses, transport, and fragmentation into microplastics (and nanoplastics). Plastic debris/microplastics arise from land disposal, wastewater treatment, tire wear, paint failure, textile washing, and at-sea losses. Riverine and atmospheric transport, storm water, and disasters facilitate releases. In surface waters plastics/microplastics weather, biofoul, aggregate, and sink, are ingested by organisms and redistributed by currents. Ocean sediments are likely the ultimate destination. Plastics release additives, concentrate environmental contaminants, and serve as substrates for biofilms, including exotic and pathogenic species. Microplastic abundance increases as fragment size decreases, as does the proportion of organisms capable of ingesting them. Particles <20 μm may penetrate cell membranes, exacerbating risks. Exposure can compromise feeding, metabolic processes, reproduction, and behavior. But more investigation is required to draw definitive conclusions. Human ingestion of contaminated seafood and water is a concern. Microplastics indoors present yet uncharacterized risks, magnified by the time we spend inside (>90%) and the abundance of polymeric products therein. Scientific challenges include improving microplastic sampling and characterization approaches, understanding long-term behavior, additive bioavailability, and organismal and ecosystem health risks. Solutions include improving globally based pollution prevention, developing degradable polymers and additives, and reducing consumption/expanding plastic reuse.

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Occurrence and Characteristics of Microplastic Pollution in Xiangxi Bay of Three Gorges Reservoir, China

Cited by 413 publications

References 53 publications

Distribution and Modeled Transport of Plastic Pollution in the Great Lakes, the World's Largest Freshwater Resource

Distribution and Modeled Transport of Plastic Pollution in the Great Lakes, the World's Largest Freshwater Resource

Occurrence and Species‐Specific Distribution of Plastic Debris in Wild Freshwater Fish from the Pearl River Catchment, China

A Global Perspective on Microplastics

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