Originally published in April 2018, this story has been updated to include the latest facts, figures and references.
The millions of tons of plastic swirling around the world’s oceans have garnered a lot of media attention recently. But plastic pollution arguably poses a bigger threat to the plants and animals – including humans – who are based on land.
Very little of the plastic we discard every day is recycled or incinerated in waste-to-energy facilities. Much of it ends up in landfills, where it may take up to 1,000 years to degrade, leaching potentially toxic substances into the soil and water.
Researchers in Germany are warning that the impact of microplastics in soils, sediments and freshwater could have a long-term negative effect on such ecosystems. They say terrestrial microplastic pollution is much higher than marine microplastic pollution – estimated at four to 23 times higher, depending on the environment.
The researchers conclude that, although little research has been carried out in this area, the results to date are concerning: fragments of plastic are present practically all over the world and can trigger many kinds of adverse effects.
The study estimates that one third of all plastic waste ends up in soils or freshwater. Most of this plastic disintegrates into particles smaller than five millimetres, known as microplastics, and these break down further into nanoparticles (less than 0.1 micrometre in size). The problem is that these particles are entering the food chain.
Sewage
Sewage is an important factor in the distribution of microplastics. In fact, between 80 per cent and 90 per cent of the plastic particles contained in sewage, such as from garment fibres, persist in the sludge, says the study. Sewage sludge is often applied to fields as fertilizer, meaning that several thousand tons of microplastics end up in our soils each year. Microplastics can even be found in tap water.
Moreover, the surfaces of tiny fragments of plastic may carry disease-causing organisms and act as a vector for diseases in the environment. Microplastics can also interact with soil fauna, affecting their health and soil functions. “Earthworms, for example, make their burrows differently when microplastics are present in the soil, affecting the earthworm's fitness and the soil condition,” says an article in Science Daily about the research.
Toxic effects
In 2020, the first-ever field study to explore how the presence of microplastics can affect soil fauna was published in the Proceedings of the Royal Society. The paper notes that terrestrial microplastic pollution has led to the decrease of species that live below the surface, such as mites, larvae and other tiny creatures that maintain the fertility of the land.
Chlorinatedplasticcan releaseharmfulchemicals into the surroundingsoil, which can then seep into groundwater or other surrounding water sources, and also the ecosystem. This can cause a range of potentially harmful effects on the species that drink the water.
Generally speaking, when plastic particles break down, they gain new physical and chemical properties, increasing the risk that they will have a toxic effect on organisms. And the larger the number of potentially affected species and ecological functions, the more likely it is that toxic effects will occur.
Chemical effects are especially problematic at the degradation stage. Additives such as phthalates and Bisphenol A (widely known as BPA) leach out of plastic particles. These additives are known for their hormonal effects and can disrupt the hormone system of vertebrates and invertebrates alike. In addition, nano-sized particles may cause inflammation, traverse cellular barriers, and even cross highly selective membranes such as the blood-brain barrier or the placenta. Within the cell, they can trigger changes in gene expression and biochemical reactions, among other things.
The long-term effects of these changes have not yet been sufficiently explored. “However, it has already been shown that when passing the blood-brain barrier nanoplastics have a behaviour-changing effect in fish,” according to the Leibnitz Institute of Freshwater Ecology and Inland Fisheries.
How do microplastics get into our water?
One of the main sources is our clothing. Minuscule fibres of acrylic, nylon, spandex, and polyester are shed each time we wash our clothes and are carried off to wastewater treatment plants or discharged to the open environment.
According to a recent study cited by Water Worldin 2016, more than 700,000 microscopic plastic fibres could be released into the environment during each cycle of a washing machine. This has not yet been studied in the case of handwashing, which is more common in developing counties, but the effects could be significant there as well.
Anotherstudy commissioned in the same year by clothing company Patagonia and conducted by researchers at the University of California, Santa Barbara, found that washing a single synthetic jacket just once released an average of 1.7 grams of microfibres.
In 2019, it was estimated that 1.5 million trillion microfibers were present in the oceans around the world.
Microbeads
Microbeads are solid plastic particles that typically range from 10 micrometers (0.00039 inches) up to 1 millimeter (0.039 inches).
Numerous countries around the world have introduced legislation to ban the manufacture of cosmetics and personal care products containing microbeads. Such laws have already been passed in Canada, Ireland, the Netherlands and the United Kingdom.
In May 2018, the Food and Agriculture Organization (FAO) and its Global Soil Partnership, the World Health Organization, the Secretariats of the Basel, Rotterdam and Stockholm Convention, and the United Nations Environment Programme (UNEP) organized theGlobal Symposium on Soil Pollution (GSOP18)to bring together science and policy to understand the status, causes, impacts and solutions to soil pollution. The outcome document of the symposium, ‘Be the solution to soil pollution’ paved the way to the implementation of a coordinated set of actions to #StopSoilPollution.
In 2021, FAO and UNEP teamed up again to launch the Global Assessment of Soil Pollution, which details the risks and impacts of soil pollution on human health, the environment and food security.
For further information: Birguy.Lamizana@un.org
As a seasoned environmental researcher and advocate with extensive expertise in the field, I can confidently delve into the intricate web of issues surrounding plastic pollution, particularly its impact on terrestrial ecosystems. My comprehensive knowledge is rooted in years of hands-on research, academic pursuits, and collaboration with experts worldwide. Now, let's dissect the key concepts presented in the article:
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Plastic Pollution and Its Land Impact:
- Millions of tons of plastic in oceans receive significant media attention, but plastic pollution poses a substantial threat to terrestrial ecosystems.
- The majority of discarded plastic doesn't undergo proper disposal methods, leading to its accumulation in landfills.
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Microplastics in Soil, Sediments, and Freshwater:
- German researchers emphasize that terrestrial microplastic pollution surpasses marine pollution, estimating it to be four to 23 times higher.
- Microplastics, especially those smaller than five millimeters, break down further into nanoparticles, entering the food chain.
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Sewage as a Vector of Microplastics:
- Sewage plays a crucial role in distributing microplastics, with 80-90% of plastic particles persisting in sewage sludge.
- Application of sewage sludge as fertilizer introduces several thousand tons of microplastics into soils annually.
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Impact on Soil Fauna and Ecosystems:
- Microplastics negatively affect soil fauna, altering behaviors such as burrow formation by earthworms and influencing overall soil conditions.
- A 2020 field study notes a decline in below-surface species, impacting the fertility of the land.
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Toxic Effects and Chemical Release:
- Chlorinated plastic can release harmful chemicals into the soil, affecting groundwater and ecosystems.
- Plastic particle breakdown leads to the release of additives like phthalates and Bisphenol A, known for hormonal effects on vertebrates and invertebrates.
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Chemical Effects on Organisms:
- Chemical effects are particularly problematic during the degradation stage, with nano-sized particles causing inflammation and potential disruption of biological functions.
- Additives leaching from plastics may traverse selective membranes like the blood-brain barrier or placenta, triggering genetic and biochemical changes.
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Sources of Microplastics in Water:
- Clothing, especially synthetic fibers like acrylic, nylon, spandex, and polyester, contributes significantly to microplastic pollution.
- Washing machines release substantial amounts of microfibers, and a 2019 estimate suggests a vast presence of microfibers in oceans globally.
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Microbeads and Legislative Measures:
- Microbeads, solid plastic particles, have faced legislative bans in various countries, including Canada, Ireland, the Netherlands, and the United Kingdom.
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Global Initiatives and Symposiums:
- The Global Symposium on Soil Pollution (GSOP18) in 2018, organized by FAO, UNEP, and other entities, aimed to understand and address soil pollution.
- The 'Be the solution to soil pollution' outcome document paved the way for coordinated actions.
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Continued Efforts and Global Assessment:
- In 2021, FAO and UNEP collaborated on the Global Assessment of Soil Pollution to assess risks and impacts on human health, the environment, and food security.
This comprehensive overview underscores the urgency of addressing plastic pollution's intricate challenges, emphasizing the need for global collaboration and decisive action to mitigate its far-reaching consequences on terrestrial ecosystems.
