Potential for Earth-friendly Plastic Replacement
Potential for Earth-friendly Plastic Replacement
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The quest to keep plastic out of landfills and simultaneously satisfy the needs of the food industry is filled with obstacles.
A biodegradable replacement for petroleum-based products has to meet all sorts of standards and, so far, attempts at viable replacements from renewable sources have faced limited success due to processing and economic constraints. Among the obstacles, products to date have been too brittle for food packaging.
But new research from The Ohio State University has shown that combining natural rubber with bioplastic in a novel way results in a much stronger replacement for plastic, one that is already capturing the interest of companies looking to shrink their environmental footprints.
Almost all plastics – about 90 percent – are petroleum-based and are not biodegradable, a major environmental concern.
In a new study published in the journal Polymers, the research team reports success with a rubber-toughened product derived from microbial fermentation that they say could perform like conventional plastic. This new study highlights the greatest success in this area so far, according to the scientists.
“Previous attempts at this combination were unsuccessful because the softness of the rubber meant the product lost a lot of strength in the process,” said lead author Xiaoying Zhao, a postdoctoral researcher in Ohio State’s Department of Food Science and Technology.
The new study involved melting rubber into a plant-based thermoplastic called PHBV along with organic peroxide and another additive called trimethylolpropane triacrylate (TMPTA).
The end product was 75 percent tougher and 100 percent more flexible than PHBV on its own – meaning it is far easier to shape into food packaging.
Other research teams have combined rubber and PHBV, but the products have been too weak to withstand all the demands of a food package – from processing, to shipping, to handling in stores and homes, especially containers that are used for freezing and then microwaving, said the study’s senior author, Yael Vodovotz, a professor of food science and technology at Ohio State.
Increased flexibility, without a significant loss of strength, is particularly important when it comes to plastic films commonly used to package everything from fresh produce to frozen foods, she said.
While other attempts at making this type of rubber-enhanced bioplastic have reduced the strength of the PHBV by as much as 80 percent, only 30 percent of the strength was lost in this study – a much more manageable amount, Zhao said.
Toughness, which was improved, is different from strength, explained study co-author Katrina Cornish, an expert in natural rubber and professor of horticulture and crop science at Ohio State.
“Imagine trying to pull a block of concrete apart with your hands. That’s testing its strength. But karate chopping it with your hand or foot is testing its toughness – how easily it breaks,” Cornish said.
“You can never pull it apart, but if you’re strong enough you can break it.”
Much of the researchers’ current focus is on the potential use of various biodegradable – and otherwise environmentally conscious – materials they might use as fillers to further strengthen the mix. They’ve discussed using the “cake” left behind after a fellow researcher extracts oil from spent coffee grounds. Tomato skins are under consideration, as are eggshells.
“We want something that would otherwise go to waste that is sustainable and also relatively cheap,” Vodovotz said.
They’re even looking at the potential to attack two environmental problems at once, by seeing how invasive grasses that environmentalists are yanking out of waterways might play with the rubber-infused mix.
“We could dry them, grind them up and potentially use these grasses as a fibrous filler,” Vodovotz said.
Beyond packaged foods, a bioplastic could potentially be used in other food-related applications such as utensils and cutting boards.
And the researchers are looking to collaborate with colleagues outside of food science to consider other applications for their product, such as to create building materials, gloves for those working in food service, or parts for cars and airplanes.
As the team works to move its technology out of the lab and into the food industry, there will be many details to work out depending on a company’s individual priorities and concerns, Vodovotz said, and that may mean tinkering with the mix.
“As we get closer and closer to working with food manufacturers, there are specific questions our potential partners are asking,” Vodovotz said. “We have to be very careful about what we use in this process in order to meet their needs, and they have very specific parameters.”
This article has been republished from materials provided by The Ohio State University. Note: material may have been edited for length and content. For further information, please contact the cited source.
Synergistic Mechanisms Underlie the Peroxide and Coagent Improvement of Natural-Rubber-Toughened Poly(3-hydroxybutyrate-co-3-hydroxyvalerate) Mechanical Performance. Xiaoying Zhao, Katrina Cornish and Yael Vodovotz. Polymers 2019, 11(3), 565; https://doi.org/10.3390/polym11030565.