Scientist appalled by Newfoundland’s underwater trash problem

Pottery, plastics and pedal bikes are just some of the underwater trash found by researchers.

A research scientist with Fisheries and Oceans Canada has been surveying what lies beneath the calm waters of harbours in Newfoundland. It isn’t pretty.

While there is debris with historical value, such as clay pottery and containers from European vessels visiting during the summer months, there is a much larger amount of trash.  It’s the more recent garbage found in our coastal environment that has Corey Morris concerned.

Barbecues and bikes

“It’s shocking,” said Morris, who is also an adjunct professor in the Department of Ocean Science at Memorial University.

“Some places it’s near impossible to see the natural bottom because its covered in so much debris.”

“Many of the new garbage contains plastic. We’re seeing vinyl siding, windows, carpet, flooring. We see household items such as fridges, stoves, washers — barbecues are very common in harbours around Newfoundland — tools [and] table saws,” he told CBC Radio’s the Broadcast.

   

Corey Morris says his most surprising find was this clothes dryer. When he opened the door he found work clothes and boots still inside. Household items and building materials were often found sitting on harbour floors. (Submitted to CBC by Corey Morris)

“And the number of pedal bikes are just incredible in our harbours for some reason.”

The purpose of the survey, conducted from 2007 to 2016, was to study the effects of harbour infrastructure on fish and fish habitat.

But over the course of almost a decade, it was the amount of underwater trash steadily accumulating that really stood out.

The researchers monitored 20 locations over the course of the survey, from the tip of the Northern Peninsula to the Southern Shore of the Avalon.

Every year they found new evidence of dumping — lawn chairs, fish trapped in discarded fishing gear, bags of garbage, clothing and rubber tires.

  A sculpin trapped in discarded fishing gear. Morris says the number of fish, both dead and alive, tangled in old gear was the most disturbing discovery. (Submitted to CBC by Corey Morris)

Widespread problem

Morris didn’t want to identify the harbours surveyed because, he said, it’s a widespread issue and not specific to any particular part of the province.

“Everywhere you go you’ve got the same problem. You can go in any harbour from one end of the province to the other and once you go down underwater, everything looks the same.”

Harbours without wharves were much cleaner, he said. But even in communities with newer wharves, the researchers saw debris appearing year after year.

“That’s what really raised my concern,” he said. “This is still happening. This is still an issue. Like, what are we doing?” …

Featured image: Beverage containers cover the floor of a harbour in Newfoundland. (Submitted to CBC by Corey Morris)

 

READ FULL ARTICLE:  What’s in your harbour? Scientist appalled by Newfoundland’s underwater trash problem

By Maggie Gillis, CBC News, 

November 21, 2017

http://www.cbc.ca/news/canada/newfoundland-labrador/harbour-garbage-newfoundland-1.4412203

 

Even Sea Creatures in the Deepest, Darkest Trenches have ingested Plastic

Plastic is probably everywhere in your life—but according to new research conducted in the very deepest parts of the ocean, that’s true even for the most remote tiny seafloor critters living almost 7 miles below the surface as well.

The tests, which were done on small shellfish found in deep-sea trenches across the Pacific Ocean, haven’t been published in a scientific journal yet and were conducted under the auspices of Sky Ocean Rescue, an anti-plastic pollution campaign run by a European media company. But this sort of finding has been expected for quite a while.

“These observations are the deepest possible record of microplastic occurrence and ingestion, indicating it is highly likely there are no marine ecosystems left that are not impacted by anthropogenic debris,” lead researcher Alan Jamieson, a senior lecturer in marine ecology at Newcastle University, in the United Kingdom, said in a press release.

Jamieson and his colleagues had already determined that these deep-sea trenches are full of plastic. But they also wanted to know how animals in that environment were interacting with the pollution that surrounds them. So they sent underwater robots down into trenches across the Pacific Ocean to collect small shellfish, which they brought back up to the surface so they could look inside their stomachs.

And those examinations were not pretty, to say the least. “The results were both immediate and startling,” Jamieson said in the press release. “There were instances where the fibers could actually be seen in the stomach contents as they were being removed.”

All told, they gathered 90 critters out of trenches ranging from 4 to 7 miles deep. More than half the animals from every single spot had plastic inside of them. This spanned a whole range of types of plastic, including textile materials like rayon and nylon, and harder plastics like polyvinyls.

According to calculations scientists published earlier this year, humans have produced a whopping 9 billion tons of plastic since figuring out how to make it in the first place. Most of that plastic has been discarded, and about 300 million tons of it have ended up in the ocean.

Once plastic reaches the ocean, it can gradually sink down to the seafloor, be carried around the globe by currents, and break down into infinitesimally small pieces. But it never actually disappears—it just lurks in the environment, waiting for scientists to come looking for it.

By Meghan Bartels, Newsweek, November 16, 2017

OCEAN POLLUTION: EVEN SEA CREATURES IN THE DEEPEST, DARKEST TRENCHES ARE FULL OF PLASTIC

http://www.newsweek.com/ocean-plastic-pollution-being-eaten-even-deepest-sea-creatures-712725

 

Plastic fibres found in tap water around the world, study reveals

Tests show billions of people globally are drinking water contaminated by plastic fibres, with 83% of samples found to be polluted.

Microplastic contamination has been found in tap water in countries around the world, leading to calls from scientists for urgent research on the implications for health. Scores of tap water samples from more than a dozen nations were analysed by scientists for an investigation by Orb Media, and overall, 83% of the samples were contaminated with plastic fibres.

The US had the highest contamination rate, at 94%, with plastic fibres found in tap water sampled at sites including Congress buildings, the US Environmental Protection Agency’s headquarters, and Trump Tower in New York. Lebanon and India had the next highest rates.

European nations including the UK, Germany and France had the lowest contamination rate, but this was still 72%. The average number of fibres found in each 500ml sample ranged from 4.8 in the US to 1.9 in Europe.

The new analyses indicate the ubiquitous extent of microplastic contamination in the global environment. Previous work has been largely focused on plastic pollution in the oceans, which suggests people are eating microplastics via contaminated seafood.

“We have enough data from looking at wildlife, and the impacts that it’s having on wildlife, to be concerned,” said Dr Sherri Mason, a microplastic expert at the State University of New York in Fredonia, who supervised the analyses for Orb. “If it’s impacting [wildlife], then how do we think that it’s not going to somehow impact us?” . . .

A magnified image of clothing microfibres from washing machine effluent.
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 A magnified image of clothing microfibres from washing machine effluent. One study found that a fleece jacket can shed as many as 250,000 fibres per wash. Photograph: Courtesy of Rozalia Project

 

A separate small study in the Republic of Ireland released in June also found microplastic contamination in a handful of tap water and well samples. “We don’t know what the [health] impact is and for that reason we should follow the precautionary principle and put enough effort into it now, immediately, so we can find out what the real risks are,” said Dr Anne Marie Mahon at the Galway-Mayo Institute of Technology, who conducted the research.

Microplastics can attract bacteria found in sewage, Mahon said: “Some studies have shown there are more harmful pathogens on microplastics downstream of wastewater treatment plants.”

Image result for microplastic found in tap water

Microplastics are also known to contain and absorb toxic chemicals and research on wild animals shows they are released in the body. Prof Richard Thompson, at Plymouth University, UK, told Orb: “It became clear very early on that the plastic would release those chemicals and that actually, the conditions in the gut would facilitate really quite rapid release.” His research has shown microplastics are found in a third of fish caught in the UK.

This research led Frank Kelly, professor of environmental health at King’s College London, to tell a UK parliamentary inquiry in 2016: “If we breathe them in they could potentially deliver chemicals to the lower parts of our lungs and maybe even across into our circulation.” Having seen the Orb data, Kelly told the Guardian that research is urgently needed to determine whether ingesting plastic particles is a health risk.

The new research tested 159 samples using a standard technique to eliminate contamination from other sources and was performed at the University of Minnesota School of Public Health. The samples came from across the world, including from Uganda, Ecuador and Indonesia.

“We really think that the lakes [and other water bodies] can be contaminated by cumulative atmospheric inputs,” said Johnny Gasperi, at the University Paris-Est Créteil, who did the Paris studies. “What we observed in Paris tends to demonstrate that a huge amount of fibres are present in atmospheric fallout.”

Plastic fibres may also be flushed into water systems,  . . . and rains could also sweep up microplastic pollution, which could explain why the household wells used in Indonesia were found to be contaminated.

In Beirut, Lebanon, the water supply comes from natural springs but 94% of the samples were contaminated. “This research only scratches the surface, but it seems to be a very itchy one,” said Hussam Hawwa, at the environmental consultancy Difaf, which collected samples for Orb.

This planktonic arrow worm, Sagitta setosa, has eaten a blue plastic fibre about 3mm long.
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This planktonic arrow worm, Sagitta setosa, has eaten a blue plastic fibre about 3mm long. Plankton support the entire marine food chain. Photograph: Richard Kirby/Courtesy of Orb Media

Bottled water may not provide a microplastic-free alternative to tap water, as the they were also found in a few samples of commercial bottled water tested in the US for Orb.

“We are increasingly smothering ecosystems in plastic and I am very worried that there may be all kinds of unintended, adverse consequences that we will only find out about once it is too late,” said Prof Roland Geyer, from the University of California and Santa Barbara, who led the study.

Mahon said the new tap water analyses raise a red flag, but that more work is needed to replicate the results, find the sources of contamination and evaluate the possible health impacts. . . .

 

By Damian Carrington, Environmental editor, The Guardian

September 6, 2017

READ FULL ARTICLE AT:

https://www.theguardian.com/environment/2017/sep/06/plastic-fibres-found-tap-water-around-world-study-reveals

Sea salt around the world is contaminated by plastic, studies show

Sea salt around the world is contaminated by plastic pollution, adding to experts’ fears that microplastics are becoming ubiquitous in the environment and finding their way into the food chain via the salt in our diets.

New studies have shown that tiny particles have been found in sea salt in the UK, France and Spain, as well as China and now the US.

Researchers believe the majority of the contamination comes from microfibres and single-use plastics such as water bottles, items that comprise the majority of plastic waste. Up to 12.7m tonnes of plastic enters the world’s oceans every year, equivalent to dumping one garbage truck of plastic per minute into the world’s oceans, according to the United Nations.

“Not only are plastics pervasive in our society in terms of daily use, but they are pervasive in the environment,” said Sherri Mason, a professor at the State University of New York at Fredonia, who led the latest research into plastic contamination in salt. Plastics are “ubiquitous, in the air, water, the seafood we eat, the beer we drink, the salt we use – plastics are just everywhere”.

Mason collaborated with researchers at the University of Minnesota to examine microplastics in salt, beer and drinking water. Her research looked at 12 different kinds of salt (including 10 sea salts) bought from grocery stores around the world.

Mason found Americans could be ingesting upwards of 660 particles of plastic each year, if they follow health officials’ advice to eat 2.3 grammes of salt per day.

The health impact of ingesting plastic is not known. Scientists have struggled to research the impact of plastic on the human body, because they cannot find a control group of humans who have not been exposed.

“Everybody is being exposed to some degree at any given time, from gestation through death,” researchers from Johns Hopkins Bloomberg School of Public Health and Arizona State University wrote in 2013. “Detectable levels of [the plastic] bisphenol A have been found in the urine of 95% of the adult population of the United States.”

Sea salt around the world is contaminated by plastic Photograph MirageC/Getty Images

. . . The research also comes after a Guardian analysis found 1m plastic bottles are purchased per minute, and that recycling efforts are failing to keep pace with production, which is expected to quadruple by 2050. Some environmentalists have said the threat of plastic pollution now “rivals climate change”.

Mason’s work adds to research on plastics in salt from other countries around the world, including in Spain and China.

In August, Spanish researchers concluded “sea products are irredeemably contaminated by microplastics” and there is “a background presence of microplastics in the environment”, in a study published in Scientific Reports in Nature. There, scientists tested 21 types of table salt and found plastic in all of them. The most common type of plastic they found was polyethylene terephthalate [PET], the material used to make plastic bottles.

This spring, a group of scientists from France, the UK and Malaysia tested 17 types of salt from eight different countries and examined what they believed were plastic particles. They found plastic in all but one sample and found the most of the plastic was from polyethylene and polypropylene.

Scientists first found plastics in salt in China in 2015. Microscopic plastic particles from face scrubs, cosmetics, and shards of plastic bottles were found in samples of 15 salt products found in Chinese grocery stores.

Some researchers, such as Mason, now believe sea salt could be more vulnerable to plastic contamination because of how it is made, through a process of dehydration of sea water.

“It is not that sea salt in China is worse than sea salt in America, it’s that all sea salt – because it’s all coming from the same origins – is going to have a consistent problem,” said Mason. “I think that is what we’re seeing.”

… Mason’s study also looked at how drinking water and beer are contaminated with plastic.  …’ We have to focus on the flow of plastic and the pervasiveness of plastics in our society and find other materials to be using instead.”

By Jessica Glenza in New York, The Guardian,

September 8, 2017

READ FULL ARTICLE at: https://www.theguardian.com/environment/2017/sep/08/sea-salt-around-world-contaminated-by-plastic-studies?CMP=share_btn_fb

 

Plastic fibres found in tap water around the world, study reveals

Tests show billions of people globally are drinking water contaminated by plastic particles, with 83% of samples found to be polluted.

Microplastic contamination has been found in tap water in countries around the world, leading to calls from scientists for urgent research on the implications for health.

Scores of tap water samples from more than a dozen nations were analysed by scientists for an investigation by Orb Media, who shared the findings with the Guardian. Overall, 83% of the samples were contaminated with plastic fibres.

The US had the highest contamination rate, at 94%, with plastic fibres found in tap water sampled at sites including Congress buildings, the US Environmental Protection Agency’s headquarters, and Trump Tower in New York. Lebanon and India had the next highest rates.

European nations including the UK, Germany and France had the lowest contamination rate, but this was still 72%. The average number of plastic fibres found in each 500ml sample ranged from 4.8 in the US to 1.9 in Europe.

The new analyses indicate the ubiquitous extent of microplastic contamination in the global environment. Previous work has been largely focused on plastic pollution in the oceans, which suggests people are eating microplastics via contaminated seafood.

“We have enough data from looking at wildlife, and the impacts that it’s having on wildlife, to be concerned,” said Dr Sherri Mason, a microplastic expert at the State University of New York in Fredonia, who supervised the analyses for Orb. “If it’s impacting [wildlife], then how do we think that it’s not going to somehow impact us?”

Mahon said there were two principal concerns: very small plastic particles [like plastic fibres] and the chemicals or pathogens that microplastics can harbour. “If the fibres are there, it is possible that the nanoparticles are there too that we can’t measure,” she said. “Once they are in the nanometre range they can really penetrate a cell and that means they can penetrate organs, and that would be worrying.” The Orb analyses caught particles of more than 2.5 microns in size, 2,500 times bigger than a nanometre.

Microplastics can attract bacteria found in sewage, Mahon said: “Some studies have shown there are more harmful pathogens on microplastics downstream of wastewater treatment plants.”

Microplastics are also known to contain and absorb toxic chemicals and research on wild animals shows they are released in the body. Prof Richard Thompson, at Plymouth University, UK, told Orb: “It became clear very early on that the plastic would release those chemicals and that actually, the conditions in the gut would facilitate really quite rapid release.” His research has shown microplastics are found in a third of fish caught in the UK.

  A magnified image of clothing microfibres from washing machine effluent. One study found that a fleece jacket can shed as many as 250,000 fibres per wash. Photograph: Courtesy of Rozalia Project

… The scale of global microplastic contamination is only starting to become clear, with studies in Germany finding fibres and fragments in all of the 24 beer brands they tested, as well as in honey and sugar. In Paris in 2015, researchers discovered microplastic falling from the air, which they estimated deposits three to 10 tonnes of fibres on the city each year, and that it was also present in the air in people’s homes. As well, a leading health expert in London has warned that people could be breathing in microparticles of plastic, with as yet unknown consequences on health.

Current standard water treatment systems do not filter out all of the microplastics, Mahon said: “There is nowhere really where you can say these are being trapped 100%. In terms of fibres, the diameter is 10 microns across and it would be very unusual to find that level of filtration in our drinking water systems.”

Bottled water may not provide a microplastic-free alternative to tapwater, as the they were also found in a few samples of commercial bottled water tested in the US for Orb.

… “We are increasingly smothering ecosystems in plastic and I am very worried that there may be all kinds of unintended, adverse consequences that we will only find out about once it is too late,” said Prof Roland Geyer, from the University of California and Santa Barbara, who led the study.

READ FULL ARTICLE at: https://www.theguardian.com/environment/2017/sep/06/plastic-fibres-found-tap-water-around-world-study-reveals

By Damian Carrington Environment editor, The Guardian, September 6, 2017

A Mission to the Pacific Plastic Patch in the South Pacific Gyre

Capt. Charles Moore, a mariner who has spent years travelling “hundreds of thousands of nautical miles” to measure the impact of plastic waste in the ocean has estimated that a “raft” of plastic debris spanning more than 965,000 square miles (2.5m sq km) is concentrated in a region of the South Pacific.  He was part of the team which discovered the first ocean “garbage patch” in the North Pacific gyre in 1997 and has now turned his attention to the South Pacific gyre.

Moore has just returned from a sampling expedition around Easter Island and Robinson Crusoe Island.

  Capt. Charles Moore has been researching the ocean for plastic since 1997. Source: ALGALITA

Although plastic is known to occur in the Southern Hemisphere gyres, very few scientists have visited the region to collect samples.

Oceanographer Dr Erik van Sebille, from Utrecht University, says the work of Capt Moore and his colleagues will help fill “a massive knowledge gap” in our understanding of ocean plastics.

“Any data we can get our hands on is good data at this point,” he told BBC News.

Capt Moore explained that the space occupied by sub-tropical gyres – areas of the ocean surrounded by circulating ocean currents – is approximately the same size as the entire land mass of the Earth, but they are now being “populated by our trash”.

… “It’s hard not to find plastic in the ocean any more,” Dr van Sebille said. “That’s quite shocking”.

  Our plastic rubbish has floated to islands that are thousands of miles from the nearest human population. Source: SPL

Capt Moore is the founder of Algalita Marine Research, a non-profit organisation aiming to combat the “plastic plague” of garbage floating in the world’s oceans.

For more than 30 years, he has transported scientists to the centre of remote debris patches aboard his research ship, Alguita.

Dragging nets behind the vessel, the crew sieves particles of plastic from the ocean, which are then counted and fed into estimates of global microplastic distribution.

Although scientists agree that plastic pollution is a widespread problem, the exact distribution of these rafts of ocean garbage is still unclear.

“If we don’t understand where the plastic is, then we don’t really understand what harm it does and we can’t really work on solving the problem,” said Dr van Sebille.

Eating rubbish

Capt Moore and his crew hope to address this lack of data through their research trips.

On this latest voyage, Capt Moore and his colleagues are also investigating how plastic in the South Pacific Ocean may be threatening the survival of fish.

Lanternfish, that live in the deep ocean, are an important part of the diet of whales, squid and king penguins and the Algalita team says that plastic ingestion by lanternfish could have a domino effect on the rest of the food chain.

Little lantern fish are smaller than your finger and live so deep that very few people have ever seen one alive.  Every night, all around the world, this false bottom of fish rises up just a bit from the depths of the sea, eats heaps of carbon-rich plankton, and then drops back down again and poops carbon.  In a world in which carbon emissions have become an enormous ecological threat, and in an era when great minds are searching for ways to achieve carbon sequestration to remove it from the atmosphere, it is amazing to consider that these tiny lantern fish sink far more carbon than all of the world’s forests combined.
 

… Christiana Boerger, a marine biologist in the US Navy, has seen the impact of oceanic garbage patches first hand, aboard the Alugita and she says that some fish species “have more man-made plastic in their stomach than their natural food”.

… Capt Moore says the South Pacific Gyre garbage patch is different from those in the Northern Hemisphere, because most of the litter appears to have come from the fishing industry.

Elsewhere, scientists are shifting their attention away from remote mid-ocean garbage patches to locations closer to home.

“If you think about plastic in terms of its impact, where does it harm marine life?” Dr van Sebille posed.

“Near coastlines is where biology suffers. It’s also where the economy suffers the most.” …

FEATURED IMAGE:  South Pacific garbage patch – Most of the plastic is made up of tiny pieces floating at the surface.  Source: ALGALITA

 

READ FULL ARTICLE AND WATCH VIDEO AT:

A mission to the Pacific plastic patch

July 16, 2017

 

If you drop plastic in the ocean, where do the ocean currents take it?

Modelling shows that ocean currents can concentrate slow-degrading debris in certain parts of the world’s oceans, leading to so-called ‘garbage patches’.

Shanghai
 A bottle dropped in the water off the coast of China is likely be carried eastward by the north Pacific gyre and end up a few hundred miles off the coast of the US. Photograph: Graphic

It is estimated that between four and 12m metric tonnes of plastic makes its way into the ocean each year. This figure is only likely to rise, and a 2016 report predicted that by 2050 the amount of plastic in the sea will outweigh the amount of fish.

. . . A lot of plastic debris in the ocean breaks down into smaller pieces and is ingested by marine life, and it is thought that a significant amount sinks to the sea bed. But a lot of it just floats around, and thanks to sophisticated modelling of ocean currents using drifting buoys, we can see where much of it ends up.

Oceanographer Erik van Sebille, who works at Imperial College London and Utrecht University in the Netherlands, has shown that thanks to strong ocean currents known as gyres, huge amounts of plastic end up in “garbage patches” around the world, the largest one being in the north Pacific.

As can be seen in the image above, a bottle dropped in the water off the coast of China, near Shanghai, is likely be carried eastward by the north Pacific gyre and end up circulating a few hundred miles off the coast of the US.

A bottle dropped off the Mexican coast, near Acapulco, is likely to be caught in the same gyre. Some of the plastic waste drifts south, but a huge amount is swept west towards Asia before floating north and ending up in the same area – the so-called Great Pacific Garbage Patch [aka Pacific Trash Vortex].

The North Atlantic is home to another powerful current. The image below shows what happens to plastic debris that enters the ocean around New York. Initially a lot of it heads over to Europe, with concentration in the Bay of Biscay and, to a lesser extent, the North Sea, but the majority is trapped by the current and ends up floating in the middle of the ocean.

It’s a similar story in the UK. A bottle dropped in the sea off Cornwall may well be dragged through the channel towards Scandinavia, but the greatest concentrations are again in the Bay of Biscay and the western North Atlantic.

India is one of the world’s biggest plastic polluters, creating more than 15,000 tonnes of plastic waste a day. The plastic waste that enters the water around Mumbai is likely to end up either being caught in the Indian Ocean gyre and floating close to Madagascar, or being swept east and into the Bay of Bengal, one of the worst places in the world for plastic pollution

You can explore further modelling on Van Sebille’s website, Plastic Adrift.

 

By Alan Evans, The Guardian

June 29, 2017

https://www.theguardian.com/environment/2017/jun/29/if-you-drop-plastic-in-the-ocean-where-does-it-end-up

Scientists find 38 million pieces of trash on Pacific island

Researchers say density of trash the highest recorded anywhere despite island’s extreme remoteness

In this 2015 photo provided by Jennifer Lavers, a crab uses a piece of plastic debris as shelter on the beach on Henderson Island. (Jennifer Lavers/Associated Press)

When researchers travelled to a tiny, uninhabited island in the middle of the Pacific Ocean, they were astonished to find an estimated 38 million pieces of trash washed up on the beaches.

Almost all of the garbage they found on Henderson Island was made from plastic. There were toy soldiers, dominos, toothbrushes and hundreds of hardhats of every shape, size and colour.

The researchers say the density of trash was the highest recorded anywhere in the world, despite Henderson Island’s extreme remoteness. The island is located about halfway between New Zealand and Chile and is recognized as a UNESCO world heritage site.

Jennifer Lavers, a research scientist at Australia’s University of Tasmania, was lead author of the report, which was published Tuesday in Proceedings of the National Academy of Sciences.

Lavers said Henderson Island is at the edge of a vortex of ocean currents known as the South Pacific gyre, which tends to capture and hold floating trash.

The quantity of plastic is ‘both beautiful and terrifying.’ (Jennifer Lavers/Associated Press)

“The quantity of plastic there is truly alarming,” Lavers told The Associated Press. “It’s both beautiful and terrifying.”

She said she sometimes found herself getting mesmerized by the variety and colours of the plastic that litters the island before the tragedy of it would sink in again.

Lavers and six others stayed on the island for 3 1/2 months in 2015 while conducting the study. They found the trash weighed an estimated 17.6 tons and that more than two-thirds of it was buried in shallow sediment on the beaches.

Lavers said she noticed green toy soldiers that looked identical to those her brother played with as a child in the early 1980s, as well as red motels from the Monopoly board game.

She said the most common items they found were cigarette lighters and toothbrushes. One of the strangest was a baby pacifier.

‘Rethink our relationship with plastic’

She said they found a sea turtle that had died after getting caught in an abandoned fishing net and a crab that was living in a cosmetics container.

By clearing a part of a beach of trash and then watching new pieces accumulate, Lavers said they were able to estimate that more than 13,000 pieces of trash wash up every day on the island, which is about 10 kilometres (6 miles) long and 5 kilometres (3 miles) wide.

Henderson Island is part of the Pitcairn Islands group, a British dependency. It is so remote that Lavers said she missed her own wedding after the boat coming to collect the group was delayed.

Researchers were astonished to find an estimated 38 million pieces of trash washed up on the beaches.(Jennifer Lavers/Associated Press)

Luckily, she said, the guests were still in Tahiti, in French Polynesia, when she showed up three days late, and she still got married.

Lavers said she is so appalled by the amount of plastic in the oceans that she has taken to using a bamboo iPhone case and toothbrush.

“We need to drastically rethink our relationship with plastic,” she said. “It’s something that’s designed to last forever, but is often only used for a few fleeting moments and then tossed away.”

Melissa Bowen, an oceanographer at the University of Auckland in New Zealand who was not involved in the study, said that winds and currents in the gyre cause the buildup of plastic items on places like Henderson Island.

“As we get more and more of these types of studies, it is bringing home the reality of plastic in the oceans,” Bowen said.

 

The Associated Press

May 16, 2017

https://www.cbc.ca/news/technology/trash-pacific-1.4117224

Researchers Race to find the Source of Microplastics Choking the World’s Oceans

Groundbreaking research into one of the world’s most complex pollution problems, microplastics, is underway at B.C. labs.  Scientists are growing increasingly concerned about microplastics in water and in the food chain, but they face some daunting challenges in the race to uncover the sources of the problem.

“We’re encountering a pollutant unlike any pollutant we’ve ever seen before,” says Dr. Peter Ross, director of ocean pollution research at the Vancouver Aquarium. “This is not a chemical pollutant, it’s a structural pollutant.”

Recent samples his team have taken off the B.C. coast contained up to 25,000 plastic particles and fibres in just one cubic metre of water.

Yes, some of it comes from plastic bags, foam packaging, cigarette butts and other remnants of the millions of tonnes of plastic debris slowly breaking down in the world’s oceans.

But there are some surprising sources, too, like laundry.

“A single sweater could release as much as 10,000 particles of microplastic fibres,” said Ross.

“That’s getting into the wastewater stream, and you have a million or two million people doing such laundry — it adds up.”

This water sample taken by researchers in B.C.’s Strait of Georgia contained an average of 3,200 plastic particles per cubic metre of ocean. Other samples off Vancouver contained up to 25,000 particles. (Vancouver Aquarium)

Sewage treatment plants may hold answers

But no one knows yet how washing your favourite fleece jacket fits into the bigger picture.

To find out, Ross is working with sewage treatment plants to measure the number and types of fibres in the water coming in, and later sampling the treated water as it flows out into the Fraser River to compare.

What they find could lead to changes in filtering techniques at treatment plants.

Water sampling is also being done out in the open ocean, revealing a mix of fibres and other microplastics, defined as anything smaller than five millimetres in size.

It’s a global issue, so everyone has an interest in reducing the amount of plastic being added to the world’s waterways. One estimate puts it at the equivalent of a garbage truckload every minute. At this rate, by 2050 there will be more plastic in the ocean than fish.

To home in on the problem, technicians at the Vancouver Aquarium lab recently began using a $325,000 infrared spectrometer like the kind usually found in crime labs.

It can identify the type of plastic from tiny samples.

‘It’s not going to give us the exact fingerprint,” says Ross. “It won’t say ‘Walmart fleece made in China,’ but it will confirm it is plastic, give us the category, tell us about additives and sometimes actually a manufacturer.”

. . .

Featured image:

This microscopic image shows a tiny zooplankton tangled in a microplastic fibre. Plankton are part of the diet for some bigger fish and give the microplastics a gateway into the food supply. (Vancouver Aquarium)

READ FULL ARTICLE:

B.C. researchers race to find the source of microplastics choking the world’s oceans

By Greg Rasmussen, CBC NEWS, March 11, 2017

http://www.cbc.ca/news/canada/british-columbia/bc-microplastics-research-1.4017502

Under a business-as-usual scenario, there will be more plastic than fish (by weight) by 2050. Plastic packaging plays a major role in the amount of plastic entering the oceans.

By 2050, the ocean is expected to contain more plastic than fish – major source: plastic packaging

Plastics and plastic packaging are an integral and important part of the global economy. Plastics production has surged over the past 50 years, from 15 million tonnes in 1964 to 311 million tonnes in 2014, and is expected to double again over the next 20 years, as plastics come to serve increasingly many applications. Plastic packaging, the focus of this report, is and will remain the largest application; currently, packaging represents 26% of the total volume of plastics used. Plastic packaging not only delivers direct economic benefits, but can also contribute to increased levels of resource productivity – for instance, plastic packaging can reduce food waste by extending shelf life and can reduce fuel consumption for transportation by bringing packaging weight down.

While delivering many benefits, the current plastics economy also has important drawbacks that are becoming more apparent by the day. Today, 95% of plastic packaging material value, or $80–120 billion annually, is lost to the economy after a short first use. More than 40 years after the launch of the first universal recycling symbol, only 14% of plastic packaging is collected for recycling. When additional value losses in sorting and reprocessing are factored in, only 5% of material value is retained for a subsequent use. Plastics that do get recycled are mostly recycled into lower-value applications that are not again recyclable after use. The recycling rate for plastics in general is even lower than for plastic packaging, and both are far below the global recycling rates for paper (58%) and iron and steel (70–90%). In addition, plastic packaging is almost exclusively single-use, especially in business-to-consumer applications.

Plastic packaging generates significant negative externalities, conservatively valued by UNEP at $40 billion and expected to increase with strong volume growth in a business-as-usual scenario. Each year, at least 8 million tonnes of plastics leak into the ocean – which
is equivalent to dumping the contents of one garbage truck into the ocean every minute. If no action is taken, this is expected to increase to two per minute by 2030 and four per minute by 2050. Estimates suggest that plastic packaging represents the major share of this leakage. The best research currently available estimates that there are over 150 million tonnes of plastics in the ocean today. In a business-as-usual scenario, the ocean is expected to contain 1 tonne of plastic for every 3 tonnes of fish by 2025, and by 2050, more plastics than fish (by weight).

  

Sea Otter chewing on discarded cookie package; Sea turtle ingesting plastic bag.

The production of plastics draws on fossil feedstocks, with a significant carbon impact that will become even more significant with the projected surge in consumption. Over 90% of plastics produced are derived from virgin fossil feedstocks. This represents, for all plastics (not just plastic packaging), about 6% of global oil consumption, which is equivalent to the oil consumption of the global aviation sector. If the current strong growth of plastics usage continues as expected, the plastics sector will account for 20% of total oil consumption and 15% of the global annual carbon budget by 2050 (this is the budget that must be adhered to in order to achieve the internationally accepted goal to remain below a 2°C increase in global warming).  Even though plastics can bring resource efficiency gains during use, these figures show that it is crucial to address the greenhouse gas impact of plastics production and afteruse treatment.

Plastics often contain a complex blend of chemical substances, of which some raise concerns about potential adverse effects on human health and the environment. While scientific evidence on the exact implications is not always conclusive, especially due to the difficulty of assessing complex long-term exposure and compounding effects, there are sufficient indications that warrant further research and accelerated action.

Many innovations and improvement efforts show potential, but to date these have proved to be too fragmented and uncoordinated to have impact at scale. Today’s plastics economy is highly fragmented. The lack of standards and coordination across the value chain has allowed a proliferation of materials, formats, labelling, collection schemes and sorting and reprocessing systems, which collectively hamper the development of effective markets. Innovation is also fragmented. The development and introduction of new packaging materials and formats across global supply and distribution chains is happening far faster than and is largely disconnected from the development and deployment of corresponding after-use systems and infrastructure. At the same time, hundreds, if not thousands, of small-scale local initiatives are launched each year, focused on areas such as improving collection schemes and installing new sorting and reprocessing technologies. Other issues, such as the fragmented development and adoption of labelling standards, hinder public understanding and create confusion.

In overcoming these drawbacks, an opportunity beckons: using the plastics innovation engine to move the industry into a positive spiral of value capture, stronger economics and better environmental outcomes.

Featured image: Blue Planet II on BBC

 

SOURCE:

The New Plastics Economy: Rethinking the future of plastics, page 7

World Economic Forum, January 2016

 

SEE ALSO:  15-Year Study Indicates Huge Increase in Pacific Ocean Microplastics

 

 

 

Seafood eaters ingest up to 11,000 plastic particles every year

Seafood eaters ingest up to 11,000 tiny pieces of plastic every year with dozens of particles becoming embedded in tissues, scientists have warned, in findings described as ‘sobering’ by the Prince of Wales.  Researchers from the University of Ghent in Belgium believe that plastic particles, aka microplastics, accumulate in the body over time and could be a long term health risk.

And they say the amount of plastic absorbed will only get worse as pollution in the oceans increases, a finding described by the Prince of Wales as ‘sobering.’  The Prince has previously described micro-particles as ‘grey goo.’

Dr Colin Janssen, who led the research, said the presence of plastic particles in the body was ‘a concern’.

. . . The study is the first comprehensive risk assessment of its kind. Scientists calculated that more than 99 per cent  of the microplastics pass through the human body – but the rest are taken up by body tissues.

Mussels feed by filtering around 20 litres of seawater a day, ingesting microplastics by accident.

Most are excreted, but on average each mussel contains one tiny fragment lodged in its body tissue. As plastic pollution builds up in the ocean that will increase.

If current trends continue, by the end of the century people who regularly eat seafood could be consuming 780,000 pieces of plastic a year, absorbing 4,000 of them from their digestive systems.

   Microplastics are widely found in mussels, oysters and other shellfish.

. . . There are more than five trillion pieces of microplastic in the world’s oceans and the equivalent of one rubbish truck of plastic waste is being added to the sea every minute.

By 2050 that will increase to four trucks every minute. The plastic in the ocean will take decades or even centuries to break down into small pieces, but many scientists believe it will never completely disappear.

Featured Image: A larval perch that has ingested microplastic particles, Credit: Oona Lonnstedt  

SEE FULL ARTICLE AT:

Seafood eaters ingest up to 11,000 tiny pieces of plastic every year, study shows 

By Sarah Knapton, science editor, The Telegraph

24 January 2017

http://www.telegraph.co.uk/science/2017/01/24/seafood-eaters-ingest-11000-tiny-pieces-plastic-every-year-study/

People may be breathing in microparticles, health expert warns

People could be breathing in microparticles of plastic, according to a leading environmental health expert, with as yet unknown consequences on health.

Microplastics are known to be damaging to life in the oceans, with marine creatures mistaking them for food, and to be consumed by people eating seafood. But Frank Kelly, a professor of environmental health at King’s College London, told MPs investigating the issue that the microparticles could be being inhaled too.

“There is a possibility, a real possibility, that some of those microparticles will be entrained into the air, and they will be carried around and we will end up breathing them,” Kelly told an evidence session of the Environmental Audit Committee (EAC), adding that his group had just started new research into the issue. “This is a horizon-scanning issue but the particles are of a size that they are [breathable], they are increasing in number in our environment and there is a question to be asked.”

Kelly said the microplastics could enter the air after sewage sludge is spread on fields and dries out. He said a French study had detected the particles in the air.

“If we breathe them in they could potentially deliver chemicals to the lower parts of our lungs and maybe even across into our circulation, in the same way as we worry about all the other vehicle-related emissions,” he said. The health effect of microplastics, either eaten or breathed in, was just beginning to be looked at, Kelly said.

Evidence submitted to the EAC by the Department of Environment, Food and Rural Affairs, said: “Even for high level consumers of seafoods that are most likely to be relatively highly contaminated with marine microplastics, dietary exposure to microplastic particles is likely to be relatively low compared with inhalation of microplastics.”

Over 10m tonnes of plastic enters the oceans every year and is worn down into trillions of pieces of plastic. Public attention in recent months has focused on one kind of microplastic, called microbeads and used as exfoliants in toiletries such as face washes and toothpastes.

Microbeads make up a small part of the total plastic waste in the seas but campaigners argue they can easily be dealt with by bans, such as the one passed by the US in December, and more than 290,000 people have signed a petition calling for a UK ban. . . .

By Damian Carrington, The Guardian

May 9, 2016

READ FULL ARTICLE AT”

https://www.theguardian.com/environment/2016/may/09/people-may-be-breathing-in-microplastics-health-expert-warns

8 million metric tonnes of plastic waste are going from the land into the oceans each year

World’s Oceans Clogged by Millions of Tons of Plastic Trash

The magnitude of plastic waste going into the ocean has been calculated: 8 million metric tons of plastic enter the oceans per year which is the equivalent of five grocery bags full of plastic trash on every 30 centimeters (foot) of every nation’s coastline around the globe.  

That’s according to scientists who released research early in 2016 estimating that a staggering 8 million metric tones of plastic pollution enter the oceans each year from the world’s 192 coastal countries based on 2010 data.

THAT’S OVER 21,000 TONS PER DAY! 8 million metric tons of plastic is equal to 16 grocery bags filled with plastic going into the ocean along every metre of coastline in the world (or five grocery bags per foot of coastline).  On our current trajectory, by 2025, this amount could double!

Major contributors are middle income countries with rapidly growing economies that have not developed sufficient waste management systems.

Based on rising waste levels, they estimated that more than 9 million tons would end up in the oceans in 2015.

Experts have sounded the alarm in recent years over how plastic pollution is killing huge numbers of seabirds, marine mammals, sea turtles and other creatures while sullying ocean ecosystems.

China was responsible for the most ocean plastic pollution per year with an estimated 2.4 million tons, about 30 percent of the global total, followed by Indonesia, the Philippines, Vietnam, Sri Lanka, Thailand, Egypt, Malaysia, Nigeria and Bangladesh.

The United States was the only rich industrialized nation in the top 20, and it ranked No. 20. Coastal EU nations combined would rank 18th. [See table below.]

The plastic trash encompasses just about anything imaginable made of plastic including shopping bags, bottles, toys, food wrappers, fishing gear, cigarette filters, sunglasses, buckets and toilet seats.

“In short, you name it and it is probably somewhere in the marine environment,” said Kara Lavender Law, a research professor of oceanography with the Massachusetts-based Sea Education Association.

The estimates were based on information including World Bank data for trash generated per person in all nations with a coastline, coastal population density, the amount of plastic waste countries produce and the quality of their waste-management practices.

“I think this is a wake-up call for how much waste we produce,” said University of Georgia environmental engineering professor Jenna Jambeck.

The researchers calculated that 275 million tons of plastic trash was generated in the 192 coastal countries that year, with an estimated 8 million tons entering the ocean and a possible range between 4.8 million and 12.7 million tons.

“The most pressing need is to capture plastic waste to prevent it from entering the environment,” Law said. “This means investing in waste management infrastructure, especially in those countries with rapidly developing economies.”

“In high-income countries, we also have a responsibility to reduce the amount of waste, especially plastic waste, that we produce,” she added.

The research was published in the journal Science. (Reporting by Will Dunham; Editing by Sandra Maler).

SOURCE:

World’s Oceans Clogged by Millions of Tons of Plastic Trash

By Will Dunham, Reuters, February 12, 2016

https://www.scientificamerican.com/article/world-s-oceans-clogged-by-millions-of-tons-of-plastic-trash/

 

infographic

The 192 countries with a coast bordering the Atlantic, Pacific and Indian oceans, Mediterranean and Black seas produced a total of 2.5 billion metric tons of solid waste. Of that, 275 million metric tons was plastic, and an estimated 8 million metric tons of mismanaged plastic waste entered the ocean in 2010. Credit: Lindsay Robinson/UGA

From Science Daily: Magnitude of plastic waste going into the ocean calculated: 8 million metric tons of plastic enter the oceans per year

Summary: How much mismanaged plastic waste is making its way from land to ocean has been a decades-long guessing game. Now scientists have put a number on the global problem. Their study found between 4.8 and 12.7 million metric tons of plastic entered the ocean in 2010 from people living within 50 kilometers of the coastline.

A plastic grocery bag cartwheels down the beach until a gust of wind spins it into the ocean. In 192 coastal countries, this scenario plays out over and over again as discarded beverage bottles, food wrappers, toys and other bits of plastic make their way from estuaries, seashores and uncontrolled landfills to settle in the world’s seas.

How much mismanaged plastic waste is making its way from land to ocean has been a decades-long guessing game. Now, the University of Georgia’s Jenna Jambeck and her colleagues in the National Center for Ecological Analysis and Synthesis working group have put a number on the global problem.

Their study, reported in the Feb. 13 edition of the journal Science, found between 4.8 and 12.7 million metric tons of plastic entered the ocean in 2010 from people living within 50 kilometers of the coastline. That year, a total of 275 million metric tons of plastic waste was generated in those 192 coastal countries.

Jambeck, an assistant professor of environmental engineering in the UGA College of Engineering and the study’s lead author, explains the amount of plastic moving from land to ocean each year using 8 million metric tons as the midpoint: “Eight million metric tons is the equivalent to finding five grocery bags full of plastic on every foot of coastline in the 192 countries we examined.”

To determine the amount of plastic going into the ocean, Jambeck “started it off beautifully with a very grand model of all sources of marine debris,” said study co-author Roland Geyer, an associate professor with the University of California, Santa Barbara’s Bren School of Environmental Science & Management, who teamed with Jambeck and others to develop the estimates.

They began by looking at all debris entering the ocean from land, sea and other pathways. Their goal was to develop models for each of these sources. After gathering rough estimates, “it fairly quickly emerged that the mismanaged waste and solid waste dispersed was the biggest contributor of all of them,” he said. From there, they focused on plastic.

“For the first time, we’re estimating the amount of plastic that enters the oceans in a given year,” said study co-author Kara Lavender Law, a research professor at the Massachusetts-based Sea Education Association. “Nobody has had a good sense of the size of that problem until now.”

The framework the researchers developed isn’t limited to calculating plastic inputs into the ocean.

“Jenna created a framework to analyze solid waste streams in countries around the world that can easily be adapted by anyone who is interested,” she said. “Plus, it can be used to generate possible solution strategies.”

Plastic pollution in the ocean was first reported in the scientific literature in the early 1970s. In the 40 years since, there were no rigorous estimates of the amount and origin of plastic debris making its way into the marine environment until Jambeck’s current study.

Part of the issue is that plastic is a relatively new problem coupled with a relatively new waste solution. Plastic first appeared on the consumer market in the 1930s and ’40s. Waste management didn’t start developing its current infrastructure in the U.S., Europe and parts of Asia until the mid-1970s. Prior to that time, trash was dumped in unstructured landfills–Jambeck has vivid memories of growing up in rural Minnesota, dropping her family’s garbage off at a small dump and watching bears wander through furniture, tires and debris as they looked for food.

“It is incredible how far we have come in environmental engineering, advancing recycling and waste management systems to protect human health and the environment, in a relatively short amount of time,” she said. “However, these protections are unfortunately not available equally throughout the world.”

Some of the 192 countries included in the model have no formal waste management systems, Jambeck said. Solid waste management is typically one of the last urban environmental engineering infrastructure components to be addressed during a country’s development. Clean water and sewage treatment often come first.

“The human impact from not having clean drinking water is acute, with sewage treatment often coming next,” she said. “Those first two needs are addressed before solid waste, because waste doesn’t seem to have any immediate threat to humans. And then solid waste piles up in streets and yards and it’s the thing that gets forgotten for a while.”

As the gross national income increases in these countries, so does the use of plastic. In 2013, the most current numbers available, global plastic resin production reached 299 million tons, a 647 percent increase over numbers recorded in 1975. Plastic resin is used to make many one-use items like wrappers, beverage bottles and plastic bags.

With the mass increase in plastic production, the idea that waste can be contained in a few-acre landfill or dealt with later is no longer viable. That was the mindset before the onslaught of plastic, when most people piled their waste–glass, food scraps, broken pottery–on a corner of their land or burned or buried it. Now, the average American generates about 5 pounds of trash per day with 13% of that being plastic.

But knowing how much plastic is going into the ocean is just one part of the puzzle, Jambeck said. With between 4.8 and 12.7 million metric tons going in, researchers like Law are only finding between 6,350 and 245,000 metric tons floating on the ocean’s surface.

“This paper gives us a sense of just how much we’re missing,” Law said, “how much we need to find in the ocean to get to the total. Right now, we’re mainly collecting numbers on plastic that floats. There is a lot of plastic sitting on the bottom of the ocean and on beaches worldwide.”

Jambeck forecasts that the cumulative impact to the oceans will equal 155 million metric tons by 2025. The planet is not predicted to reach global “peak waste” before 2100, according to World Bank calculations.

“We’re being overwhelmed by our waste,” she said. “But our framework allows us to also examine mitigation strategies like improving global solid waste management and reducing plastic in the waste stream. Potential solutions will need to coordinate local and global efforts.”

Story Source:

The above post is reprinted from materials provided by the University of Georgia. The original item was written by Stephanie Schupska. Note: Materials may be edited for content and length.

Journal Reference:

R. Jambeck, R. Geyer, C. Wilcox, T. R. Siegler, M. Perryman, A. Andrady, R. Narayan, K. L. Law. Plastic waste inputs from land into the oceanScience, 2015; 347 (6223): 768 DOI:10.1126/science.1260352

Cite this page:

University of Georgia. “Magnitude of plastic waste going into the ocean calculated: 8 million metric tons of plastic enter the oceans per year.” ScienceDaily. ScienceDaily, 12 February 2015.
https://www.sciencedaily.com/releases/2015/02/150212154422.htm

Study:

Plastic waste inputs from land into the ocean

Jenna R. Jambeck,Roland Geyer,2 Chris Wilcox,3 Theodore R. Siegler,4 Miriam Perryman,1 Anthony Andrady,5 Ramani Narayan,6 Kara Lavender Law7

http://www.iswa.org/fileadmin/user_upload/Calendar_2011_03_AMERICANA/Science-2015-Jambeck-768-71__2_.pdf

FROM THE ABOVE REPORT:

More than 5 trillion plastic pieces afloat at sea

In a 2014 study, it was estimated that AT LEAST 5.25 TRILLION PLASTIC PIECES, WEIGHING 269,000 METRIC TONS ARE CURRENTLY FLOATING AT SEA and that:

  • 92% is comprised of small fragments (0.33-4.75 mm).
  • Of larger items (>200mm), foamed polystyrene items were the most frequently observed.
  • During fragmentation plastics are lost from the sea surface.

This does not include the massive amount of plastic that sinks (extremely difficult to determine because of the huge depths of the ocean), washes up on beaches and seashores, or has been ingested by organisms.

German beer found to be contaminated with microplastic

New research has revealed the extent to which German beer may be contaminated by foreign substances, most notably, microplastics.

The research, published this month in Food Additives and Contaminants: Part A, analysed 24 beer samples from local supermarkets and included both alcoholic and non-alcoholic beer. Contamination was found in all cases. Defining microplastics as ‘fibres, films, fragments or granular particles smaller than 5 mm in size and made of synthetic polymers’, the authors found that regular tap water may also be subject to this contamination.

Though contamination was found in all instances, it was not possible to establish any one microplastic as being more dominant than the others. Indeed, the contributions ranged from 5% to 71% for granular material, from 14% to 87% for fragments and from 3% to 57% for fibres and varied depending on the brand of the beer.

The study also indicated that the contamination wasn’t just caused by microplastics, indeed one beer sample even contained an almost complete insect belonging to the Order Thysanoptera. Moreover, three samples revealed glass shards of up to about 600 μm size.

The authors of the article, Gerd Liebezeit & Elisabeth Liebezeit, conclude their research by suggesting possible causes for the contamination, citing the materials used in the production process and the clothes and skin of brewery workers as likely sources.

Story Source:

Materials provided by Taylor & FrancisNote: Content may be edited for style and length.


Journal Reference:

  1. Gerd Liebezeit, Elisabeth Liebezeit. Synthetic particles as contaminants in German beersFood Additives & Contaminants: Part A, 2014; 31 (9): 1574 DOI: 10.1080/19440049.2014.945099

Cite This Page:

Taylor & Francis. “How much may German beers be contaminated by microplastics?.” ScienceDaily. ScienceDaily, 3 September 2014. <www.sciencedaily.com/releases/2014/09/140903091949.htm>.