Inspiring: Microplastic Solutions News Articles
There seems to be no part of the planet that is unaffected by the pervasiveness of microplastics, from being found in human veins, human lungs, flying insects, and in 90% of table salt, to heavily polluting our skies and now spiraling around the globe through Earth’s atmosphere. Below are key excerpts of inspiring news articles on solutions to the microplastics crisis. If any link fails to function, a paywall blocks full access, or the article is no longer available, try these digital tools.
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When wildfires burned across Northern California in October 2017, they killed at least 43 people and displaced another 100,000. The human toll alone was dire, but the fires also left behind a toxic mess. The charred detritus of paint, pesticides, cleaning products, electronics, pressure-treated wood, and propane tanks left a range of pollutants in the soilincluding arsenic, asbestos, copper, hexavalent chromium, lead, and zinc. In Sonoma County, a coalition of fire remediation experts, local businesses, and ecological activists mobilized to cleanse the foundations of burned-out buildings with mushrooms. The Fire Remediation Action Coalition placed more than 40 miles of wattlesstraw-filled, snakelike tubes designed to prevent erosioninoculated with oyster mushrooms around parking lots, along roads, and across hillsides. Their plan? The tubes would provide makeshift channels, diverting runoff from sensitive waterways. The mushrooms would do the rest. The volunteers, led by Sebastopol-based landscape professional Erik Ohlsen, are advocates for mycoremediation, an experimental bioremediation technique that uses mushrooms to clean up hazardous waste, harnessing their natural ability to use enzymes to break down foreign substances. Mushrooms [have been used to] clean up oil spills in the Amazon, boat fuel pollution in Denmark, contaminated soil in New Zealand, and polychlorinated biphenyls, more commonly known as PCBs, in Washington state’s Spokane River. Research suggests mushrooms can convert pesticides and herbicides to more innocuous compounds, remove heavy metals from brownfield sites, and break down plastic. They have even been used to remove and recover heavy metals from contaminated water. Research suggests mushrooms can convert pesticides and herbicides to more innocuous compounds, remove heavy metals from brownfield sites, and break down plastic.
Note: The stunningly beautiful documentary Fantastic Fungi takes you on an amazing journey through the wild and wonderful world of mushrooms. Explore a treasure trove of concise summaries of incredibly inspiring news articles which will inspire you to make a difference.
Could plants be the answer to the looming threat of microplastic pollution? Scientists at UBC’s BioProducts Institute found that if you add tannins—natural plant compounds that make your mouth pucker if you bite into an unripe fruit—to a layer of wood dust, you can create a filter that traps virtually all microplastic particles present in water. While the experiment remains a lab set-up at this stage, the team is convinced that the solution can be scaled up easily and inexpensively. For their study, the team analyzed microparticles released from popular tea bags made of polypropylene. They found that their method (they’re calling it “bioCap”) trapped from 95.2 per cent to as much as 99.9 per cent of plastic particles in a column of water, depending on plastic type. When tested in mouse models, the process was proved to prevent the accumulation of microplastics in the organs. Dr. Rojas, a professor in the departments of wood science, chemical and biological engineering, and chemistry at UBC, adds that it’s difficult to capture all the different kinds of microplastics in a solution, as they come in different sizes, shapes and electrical charges. “There are microfibres from clothing, microbeads from cleansers and soaps, and foams and pellets from utensils, containers and packaging. By taking advantage of the different molecular interactions around tannic acids, our bioCap solution was able to remove virtually all of these different microplastic types.”
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Certain mushroom species have the ability to consume polyurethane, one of the main ingredients in plastic products. Some scientists believe that these natural composters could be the key to cleaning up our planet. Mycoremediation is the natural process that fungi use to degrade or isolate contaminants in the environment. A 2020 study published in Biotechnology Reports found that mycoremediation applied to agricultural wastes like pesticides, herbicides, and cyanotoxins is more cost-effective, eco-friendly, and effective. A project using the mycelium (the vegetative part of the mushroom similar to a plant’s root system) of two common mushrooms made headlines in 2014. Using Pleurotus ostreatus, also known as the oyster mushroom, and Schizophyllum commune, aka the split gill mushroom, the team was able to turn plastic into human-grade food. The mushrooms were cultivated on circular pods made of seaweed-derived gelatin filled with UV-treated plastics. As the fungus digests the plastic, it grows around the edible base pods to create a mycelium-rich snack after just a few months. According to a study by the University of Rajasthan in India, plastic-eating mushrooms can sometimes absorb too much of the pollutant in their mycelium, and therefore cannot be consumed. If more research is performed regarding the safety aspects, however, mycoremediation through mushroom cultivation could perhaps address two of the world’s greatest problems: waste and food scarcity.
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Scientists have developed a "self-digesting plastic", which, they say, could help reduce pollution. Polyurethane is used in everything from phone cases to trainers, but is tricky to recycle and mainly ends up in landfill. However, researchers have come up with a sci-fi like solution. By incorporating spores of plastic-eating bacteria they've developed a plastic that can self-destruct. The spores remain dormant during the useful lifetime of the plastic, but spring back to life and start to digest the product when exposed to nutrients in compost. There's hope "we can mitigate plastic pollution in nature", said researcher Han Sol Kim, of the University of California San Diego, La Jolla. And there might be an added advantage in that the spores increase the toughness of the plastic. "Our process makes the materials more rugged, so it extends its useful lifetime," said co-researcher, Jon Pokorski. "And then, when it's done, we're able to eliminate it from the environment, regardless of how it's disposed." The plastic is currently being worked on at the laboratory bench but could be in the real world within a few years, with the help of a manufacturer, he added. The type of bacteria added to the plastic is Bacillus subtilis, widely used as a food additive and a probiotic. Crucially, the bacteria has to be genetically engineered to be able to withstand the very high temperatures needed to make plastic.
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At first glance there's nothing particularly remarkable about waxworms. The larval form of wax moths, these pale wriggling grubs feed on the wax that bees use to make their honeycomb. For beekeepers, the pests are something to swiftly get rid of without a second thought. But in 2017 molecular biologist Federica Bertocchini ... stumbled on a potentially game-changing discovery about these creatures. Bertocchini, an amateur beekeeper, threw some of the waxworms in a plastic bag after cleaning her hive, and left them alone. A short time later, she noticed the worms had started producing small holes in the plastic, which begun degrading as soon as it touched the worms' mouths. The worms were doing something that we as humans find remarkably difficult to do: break down plastic. Not only that, but the worms appeared to be digesting the plastic as though it was food. Bertocchini and her fellow researchers began collecting the liquid excreted from the worms' mouths. They found this "saliva" contained two critical enzymes, Ceres and Demeter – named after the Roman and Greek goddesses of agriculture, respectively – which were able to oxidise the polyethylene in the plastic, essentially breaking down that material on contact. Bertocchini is now chief technology officer at bioresearch startup Plasticentropy France, working with a team to study the viability of scaling up these enzymes for widespread use in degrading plastic.
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Humans have created 8 billion metric tons of plastic. More than half the plastic ever produced —some 5 billion metric tons — lies smeared across the surface of the Earth. Chemists were creating “synthetic” plastics decades before the oil industry took off, from, among other materials, waste oat husks and vegetable oil. One of the tacks toward more sustainable plastics is to turn back to such biological sources. The ideal materials are not just biodegradable but also compostable — a narrower category that indicates the material can break down into organic components that are harmless to plants and animals. Compostability, unfortunately, is not easily achieved. The natural world already supplies promising polymers that are all compostable, says David Kaplan, a biomedical engineer at Tufts University. [Physicist Eleftheria] Roumeli, for example, has mined the promise of algal cells. They’re small, and therefore easily manipulable; they contain large amounts of proteins, which are biological polymers, alongside other useful materials. She and her students took powdered algae and passed it through a hot presser. After several trials ... they found they could produce a material that was stronger than many commodity plastics. The material was also recyclable: It could be ground back to powder and pressed again. If it were to be carelessly tossed into the dirt, the material would break apart at the same rate as a banana peel.
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Dead flies could be turned into biodegradable plastic, researchers have said. The finding, presented at the autumn meeting of the American Chemical Society (ACS), could be useful as it is difficult to find sources for biodegradable polymers that do not have other competing uses. “For 20 years, my group has been developing methods to transform natural products – such as glucose obtained from sugar cane or trees – into degradable, digestible polymers that don’t persist in the environment,” said the principal investigator, Karen Wooley. A colleague suggested she could use waste products left over from farming black soldier flies. The larvae of the flies contain proteins and other nutritious compounds so are being raised for animal feed. However, adult flies are less useful and are discarded. Wooley’s team has been trying to use these carcasses to make useful materials from a waste product. The researchers found that chitin, a sugar-based polymer, is a major component of the flies and it strengthens the shell, or exoskeleton, of insects and crustaceans. From the fly products, the team created a hydrogel that can absorb 47 times its weight in water in just one minute. This product could be used in cropland soil to capture flood water and then slowly release moisture during droughts. The scientists hope they will soon be able to create bioplastics such as polycarbonates or polyurethanes, which are traditionally made from petrochemicals, from the flies. These plastics will not contribute to the plastic pollution problem.
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Huge amounts of plastic ends up rivers and oceans every year, harming the environment and potentially also human health. But what if we could pull it out of water with the power of magnets? [Chemistry student] Ferreira became determined to find a solution to remove microplastics from water. He started by designing his own spectrometer, a scientific instrument that uses ultraviolet light to measure the density of microplastics in solutions. "I could see there were a lot of microplastics in the water and they weren't just coming from big plastic breaking down in the sea," he says. It was on his local beach that Ferreira came up with a solution that could extract microplastics from water. "I found some oil spill residue with loads of plastic attached to it," he says. "I realised that oil could be used to attract plastic." Ferreira mixed vegetable oil with iron oxide powder to create a magnetic liquid, also known as ferrofluid. He then blended in microplastics from a wide range of everyday items, including plastic bottles, paint and car tyres, and water from the washing machine. After the microplastics attached themselves to the ferrofluid, Ferreira used a magnet to remove the solution and leave behind only water. Following 5,000 tests, Ferreira's method was 87% effective at extracting microplastics from water. Ferreira is currently in the process of designing a device which uses the magnetic extraction method to capture microplastics as water flows past it. The device will be small enough to fit inside waterpipes to continuously extract plastic fragments.
Note: Researchers from Australia are also finding innovative ways to rapidly remove hazardous microplastics from water using magnets. Explore a treasure trove of concise summaries of incredibly inspiring news articles which will inspire you to make a difference.
Microplastics — solid plastic particles up to five millimeters in size that are not biodegradable — are pretty much everywhere. They have been detected in over 1,500 different marine animal species. They also find their way into our bodies via the water cycle and the food chain. In fact, the average person consumes up to five grams of microplastics per week. The European Union has now banned intentionally added microplastics. This applies to plastic glitter or polyethylene particles used as abrasives in scrubs, shower gel and toothpaste (these have been banned in the US since the 2015 Microbead-Free Waters Act). Under the terms of the ban, some products, such as plastic glitter found in creams or eye shadow, have been granted a transitional period to give manufacturers a chance to develop new designs. LUSH and The Body Shop are among the companies that have long been offering natural alternatives, using ground nuts, bamboo, sea salt and sugar. Beiersdorf AG ... has not used microbeads for exfoliation purposes since 2015. Instead, it has used, for example, cellulose particles or shredded apricot kernels. Since the end of 2019, all Beiersdorf wash-off products have been free of microplastics. Before the EU ban, Germany stopped providing public funding for artificial turf pitches with granules containing a high proportion of microplastic. As a result, the country already has hundreds of pitches that are filled with cork and sand instead of microplastics.
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For millennia, humans have used dried natural sponges to clean up, to paint and as vessels to consume fluids like water or honey. Whether synthetic or natural, sponges are great at ensnaring tiny particles in their many pores. And, as scientists around the world are beginning to show, sponges’ cavity-filled forms mean they could provide a solution to one of our era’s biggest scourges: microplastic pollution. In August, researchers in China published a study describing their development of a synthetic sponge that makes short work of microscopic plastic debris. In tests, the researchers show that when a specially prepared plastic-filled solution is pushed through one of their sponges, the sponge can remove both microplastics and even smaller nanoplastics from the liquid. Optimal conditions allowed the researchers to remove as much as 90 percent of the microplastics. The plastic-gobbling sponges are made mostly from starch and gelatin. Looking a bit like large white marshmallows, the biodegradable sponges are so light that balancing one atop a flower leaves the plant’s petals upright and unyielding, which the researchers suggest ought to make them cheap and easy to transport. The sponges, if ever produced at an industrial scale ... could be used in wastewater treatment plants to filter microplastics out of the water or in food production facilities to decontaminate water. It would also be possible to use microplastic-trapping sponges like this in washing machines.
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High in the Swiss Alps and the Arctic, scientists have discovered microbes that can digest plastics–importantly, without the need to apply excess heat. Their findings, published this month in the journal Frontiers in Microbiology, could one day improve plastic recycling. It's no secret that plastic pollution is a big, global issue. Since its production exploded during and after World War II, humans have created more than 9.1 billion tons of plastic–and researchers estimate that less than one tenth of the resulting waste has been recycled. To make matters worse, the most common recycling option–when plastic is washed, processed and turned into new products–doesn't actually reduce waste: The recycled materials are often lower quality and might later end up in a landfill all the same. Researchers are looking for solutions to the plastics problem. One process they've experimented with is breaking down plastics using microorganisms. Enzymes from the microorganisms found in the Arctic and Swiss Alps ... were able to break down biodegradable plastics at 59 degrees Fahrenheit. "These organisms could help to reduce the costs and environmental burden of an enzymatic recycling process for plastic," co-author Joel RÄthi [said]. Of the total 34 types of microbes examined, 19 were successfully able to break down a form of plastic called polyester-polyurethane, and 17 could break down two types of biodegradable plastic mixtures.
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The holy grail of plastic a material that can be repeatedly recycled without any loss of quality has been created by scientists. Placed in an acid bath, it can be fully broken down into its component parts. Like lego, these monomers can then be reassembled into different shapes, colours and textures, according to the scientists at Californias Lawrence Berkeley National Laboratory who created it. Currently, less than a third of recyclable plastic is re-purposed to create new materials, leaving the majority of it to end up in landfill or the ocean. The new material called poly (diketoenamine) or PDK can, unlike normal plastics, have its monomers separated by dunking the material in a highly acidic solution. The acid breaks the bonds between monomers and separates them from additives that give the plastic its distinctive look and feel. These monomers can be recovered for reuse for as long as possible, or upcycled to make another product. Were interested in the chemistry that redirects plastic lifecycles from linear to circular. We see an opportunity to make a difference for where there are no recycling options, said Brett Helms, a staff scientist in Berkeley Labs Molecular Foundry. Dr Helms added: With PDKs, the immutable bonds of conventional plastics are replaced with reversible bonds that allow the plastic to be recycled more effectively. The research team believe their recyclable plastic could be an alternative to non-recyclable plastics in use today.
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A microbrewery in Delray Beach, Florida has devised a crafty solution to plastic six-pack rings that often wreak havoc on marine wildlife. After years of research and development, Saltwater Brewery has introduced six-pack rings made of wheat and barley. The brewery developed the rings with a start-up company called E6PR. Whereas plastic rings can become tangled in the wings of sea birds, warp the shells of growing sea turtles and choke seals, Saltwater Brewery's new rings are not only biodegradable but also perfectly edible. "E6PR hopes other breweries - both small and large - will buy into the new rings and help bring costs down," Nola.com reports. The Louisiana State University (LSU) reports that the Gulf of Mexico has one of the highest concentrations of marine plastic in the world. Every net that LSU dipped into the Gulf's water came up with some form of plastic. "We found it every time," LSU's Mark Benfield [said]. E6PR is testing the edible rings with "a select group of craft breweries," but the company is not yet ready to discuss specifics.
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